Pursuant to 35 U.S.C. §119(a), this application claims the benefit of an earlier filing date of and the right of priority to Korean Application No. 10-2015-0150482, filed in Korea on Oct.r 28, 2015, the contents of which are incorporated by reference herein in its entirety.
1. Field
A compressor and a method for controlling a compressor are disclosed herein.
2. Background
In general, a compressor is an apparatus that converts mechanical energy into compression energy of a compressible fluid, and constitutes a part of a refrigerating device, for example, a refrigerator, or an air conditioner. Compressors are roughly classified into a reciprocating compressor, a rotary compressor, and a scroll compressor. The reciprocating compressor is configured such that a compression space, into and from which an operating gas, such as a refrigerant, is suctioned and discharged, is formed between a piston and a cylinder and the refrigerant is compressed as the linearly reciprocates in the cylinder. The rotary compressor is configured such that a compression space, into and from which an operating gas, such as a refrigerant, is suctioned and discharged, is formed between an eccentrically-rotatable roller and a cylinder and the refrigerant is compressed as the roller eccentrically rotates along an inner wall of the cylinder. The scroll compressor is configured such that a compression space, into and from which an operating gas, such as a refrigerant, is suctioned and discharged, is formed between an orbiting scroll and a fixed scroll and the refrigerant is compressed as the orbiting scroll rotates along the fixed scroll.
The reciprocating compressor sucks, compresses, and discharges a refrigerant by linearly reciprocating the piston within the cylinder. The reciprocating compressor is classified into a recipro type and a linear type according to a method of driving the piston.
The recipro type refers to a type of reciprocating compressor that converts a rotary motion of a motor into a linear reciprocating motion by coupling the motor to a crankshaft and coupling a piston to the crankshaft. On the other hand, the linear type refers to a type of reciprocating compressor that reciprocates a piston using a linear motion of a linearly-moving motor by connecting the piston to a mover of the motor.
The reciprocating compressor includes a motor unit or device that generates a driving force, and a compression unit or device that compresses fluid by receiving the driving force from the motor unit. A motor is generally used as the motor unit, and specifically, the linear type reciprocating compressor uses a linear motor.
The linear motor directly generates a linear driving force, and thus, does not require a mechanical conversion device and a complicated structure. Also, the linear motor may reduce a loss due to energy conversion, and remarkably reduce noise by virtue of the non-existence of a connection portion at which friction and abrasion are caused. Also, when the linear type reciprocating compressor (hereinafter, referred to as a “linear compressor”) is applied to a refrigerator or air conditioner, a compression ratio may vary by changing a stroke voltage applied to the linear compressor. Accordingly, the compressor may also be used for a control of varying a freezing capacity.
In the linear compressor, as the piston is reciprocated without being mechanically locked within the cylinder, the piston may collide with (or crash into) a wall of the cylinder when an excessive voltage is applied suddenly, or a compression may not be properly executed when the piston fails to move forward due to a great load. Therefore, a control device for controlling the motion of the piston in response to a variation of the load or voltage is needed.
In general, a compressor control device executes a feedback control by detecting voltage and current applied to a compressor motor and estimating a stroke in a sensor-less manner. In this instance, the compressor control device includes a triac or an inverter that controls the compressor.
The linear compressor performing the feedback control can detect a top dead center (TDC) of the piston only after the piston collides with a discharge valve provided on a discharge unit or device of the cylinder, thereby generating noise due to the collision between the piston and the discharge valve. That is, when the piston collides with the discharge valve in the general linear compressor, a stroke estimation is executed to determine that the piston reaches the TDC of the cylinder. Accordingly, collision noise between the piston and the discharge valve is inevitable.
Embodiments will be described in detail with reference to the following drawings in which like reference numerals refer to like elements, and wherein:
Hereinafter, description will be given in detail of embodiments disclosed herein with reference to the accompanying drawings. It should be noted that technological terms used herein are merely used to describe embodiments, but not to limit the embodiments. Also, unless particularly defined otherwise, technological terms used herein should be construed as a meaning that is generally understood by those having ordinary skill in the art to which the invention pertains, and should not be construed too broadly or too narrowly. Further, if technological terms used herein are wrong terms unable to correctly express the spirit, then they should be replaced by technological terms that are properly understood by those skilled in the art. In addition, general terms used should be construed based on the definition of dictionary, or the context, and should not be construed too broadly or too narrowly.
As illustrated in
Therefore, for designing the recipro type compressor, when the specifications of the crankshaft and the connecting rod are decided within a range of a TDC, piston 1c does not collide with a discharge unit or device 2a disposed or provided on or at one end of the cylinder 2, even without applying a separate motor control algorithm.
In this instance, the discharge unit 2a disposed or provided in the recipro type compressor may be fixed to the cylinder 2. For example, the discharge unit 2a may include a suction valve 3a, a discharge valve 4a, and a valve plate. That is, as illustrated in
However, unlike a linear type compressor to be explained later, the recipro type compressor generates friction among the crankshaft, the connecting rod, and the piston, and thus, has more factors generating the friction than the linear type compressor.
The controller of the linear compressor illustrated in
The discharge unit 2b illustrated in
Hereinafter,
As illustrated in
Referring to
Also, a value obtained by subtracting the phase difference θ from 180° may form the inflection point at the time point at which the piston reaches the TDC. A cosine value case of the phase difference may form the inflection point at the time point at which the piston reaches the TDC. In addition, even a gas constant Kg as a variable related to the reciprocating motion of the piston may form the inflection point at the time point at which the piston reaches the TDC. An embodiment for calculating the gas constant Kg will be described later with reference to Equation 2.
Referring to
As illustrated in
In an area A3 where the piston moves over the TDC, an entire load area may increase in response to the increase in the stroke x. The area A3 is defined as an over-stroke area.
The controller of the related art linear compressor may detect a motor current using a current sensor, detect a motor voltage using a voltage sensor, and estimate a stroke x based on the detected motor current or motor voltage. Accordingly, the controller may calculate the phase difference 8 between the motor voltage or motor current and the stroke x. When the phase difference 8 generates (forms) an inflection point, the controller may determine that the piston reaches the TDC, and thus, control the linear motor such that a moving direction of the piston is switched. Hereinafter, the operation that the controller of the linear compressor controls the motor such that the piston does not move over the TDC to prevent the collision between the piston and the discharge unit disposed on one end of the cylinder is referred to as “related art TDC control.”
When the related art TDC control of the linear compressor illustrated in
Also, as illustrated in
To solve those problems, a compressor according to embodiments disclosed herein may include the linear motor, and a discharge unit or device with a valve plate. In this instance, for the compressor including the discharge unit with the valve plate, the cylinder, and the valve plate may be fixedly coupled to each other, and thus, the related art TDC control cannot be applied. That is, in the related art TDC control of the compressor having the linear motor, the collision between the discharge unit and the piston is inevitably caused, like a precondition. Therefore, a TDC control method different from the related TDC control is needed for the compressor including the linear motor according to embodiments disclosed herein, in which the valve plate is fixed to one end of the cylinder.
The compressor according to embodiments disclosed herein may include a pressure changing unit or device that changes a variation rate of pressure applied to the piston before the piston reaches a virtual discharge surface (VDS) during a reciprocating motion, to prevent the piston from colliding with the discharge unit. Also, the controller of the linear compressor may detect a time point at which the pressure applied to the piston or the variation rate of the pressure changes, and control the linear motor to prevent the piston from colliding with the discharge unit on the basis of the detected time point.
The “VDS” may be defined as a surface brought into contact with at least a portion of the discharge unit. That is, as illustrated in
The VDS may be formed to be brought into contact with at least a portion of the valve plate, the discharge valve, or the suction valve. In this manner, the VDS may variably be defined according to a user's design.
Another compressor according to embodiments may include a controller that calculates a stroke of the piston using a motor current, generates a parameter associated with a position of the piston using the motor current and the calculated stroke and controls the linear motor based on the generated parameter, and a changing unit that changes a variation rate of the generated parameter before the piston reaches the VDS within the cylinder during a reciprocating motion. The VDS may be formed on at least a portion of the discharge unit facing the cylinder.
Another compressor according to embodiments may include a controller that calculates a phase difference between a motor current and a stroke, and a changing unit that changes a variation rate of the calculated phase difference before the piston reaches the VDS during a reciprocating motion. Another compressor according to embodiments may include a controller that generates a preset or predetermined signal before the piston reaches the discharge unit when the piston moves close the discharge unit during a reciprocating motion, to prevent the collision between the piston and the discharge unit.
Another compressor according to embodiments may include a controller that determines whether the piston has passed through an arranged position of an additional volume unit within the cylinder using a detected motor voltage or motor current, and controls the linear motor based on the determination result. Another compressor according to embodiments may include a pressure changing unit or device that changes a pressure applied to the piston or a variation rate of the pressure before the piston reaches the valve plate during a reciprocating motion. Also, a controller of the linear compressor according to embodiments may detect a time point at which a pressure or a variation rate of the pressure changes, and control the piston not to collide with the valve plate based on the detected time point.
In the related art TDC control, a time point at which a variable associated with the phase difference between the motor current and the stroke of the piston forms the inflection point is detected, and determines whether the piston reaches the TDC. However, it is difficult to detect the change in the pressure applied to the piston or the variation rate of the pressure, which is generated by the pressure changing unit, merely using the variable associated with the phase difference. Therefore, the controller of the linear compressor according to embodiments may generate a new parameter by applying a motor current and motor voltage detected in real time to a preset or predetermined transformation equation, in order to determine whether the pressure applied to the piston or predetermined or the variation rate of the pressure has been changed by the pressure changing unit.
As such, the grooves 32 and 34 provided in the cylinders of the compressors of
However, the groove formed on the inner wall of the cylinder for improving reliability of the compressor is designed without taking into account a dead volume of a compression space within the cylinder, which causes difficulty in maintaining performance of the compressor. Also, the reciprocating motion of the piston is executed without considering a spaced distance between one end of the cylinder on which the discharge unit is provided and the groove, thereby failing to prevent the collision between the discharge unit and the piston.
Therefore, to prevent the collision between the piston and the discharge unit, a compressor control to be explained in the following description, namely, a method for controlling a compressor capable of detecting a time point at which the piston passes through the groove is required.
Hereinafter, embodiments for solving those problems and thusly-obtained effects will be described.
Hereinafter, description will be given with reference to
As illustrated in
In addition, referring to
The components of the control device illustrated in
Hereinafter, each component will be described.
The voltage detector 21 may detect the motor voltage applied to the motor. According to one embodiment, the voltage detector 21 may include a rectifying portion and a DC link portion. The rectifying portion may output a DC voltage by rectifying AC power having a predetermined size of voltage, and the DC link portion 12 may include two capacitors.
The current detector 22 may detect the motor current applied to the motor. According to one embodiment, the current detector 22 may detect a current flowing on a coil of the compressor motor.
The stroke estimator 23 may calculate a stroke estimation value using the detected motor current and motor voltage and the motor parameter, and apply the calculated stroke estimation value to the comparer 24. In this instance, the stroke estimator 23 may calculate the stroke estimation value using the following Equation 1, for example.
Where, x denotes a stroke, a denotes a motor constant or counter electromotive force, VM denotes a motor voltage, i denotes a motor current, R denotes resistance, and L denotes inductance.
Accordingly, the comparer 24 may compare the stroke estimation value with the stroke command value and apply a difference signal of the values to the controller 25. The controller 25 may thus control the stroke by varying the voltage applied to the motor. That is, the controller 25 may reduce the motor voltage applied to the motor when the stroke estimation value is greater than the stroke command value, while increasing the motor voltage when the stroke estimation value is smaller than the stroke command value.
As illustrated in
This embodiment may be applied to any type or shape of linear compressor if the control device for the linear compressor or a compressor control device is applicable thereto. The linear compressor according to the embodiment illustrated in
In general, a motor applied to a compressor may include a stator with a winding coil and a mover with a magnet. The mover may perform a rotary motion or reciprocating motion according to interaction between the winding coil and the magnet.
The winding coil may be configured in various forms according to a type of motor. For example, the winding coil of a rotary motor may be wound on a plurality of slots, which may be formed on an inner circumferential surface of a stator in a circumferential direction, in a concentrated or distributed manner. For a reciprocating motor, the winding coil may be formed by winding a coil into a ring shape and a plurality of core sheets may be inserted to an outer circumferential surface of the winding coil in a circumferential direction.
Specifically, for the reciprocating motor, the winding coil may be formed by winding the coil into the ring shape. Thus, the winding coil is typically formed by winding a coil on an annular bobbin made of a plastic material.
As illustrated in
An outer stator 131 and an inner stator 132 of a reciprocating motor 130 which constitutes a motor unit or motor M are fixed to the frame 120, and a mover 133 which performs a reciprocating motion may be interposed between the outer stator 131 and the inner stator 132. A piston 142 constituting a compression unit or device Cp together with a cylinder 141 to be explained later may be coupled to the mover 133 of the reciprocating motor 130.
The cylinder 141 may be disposed or provided in a range overlapping the stators 131 and 132 of the reciprocating motor 130 in an axial direction. A compression space CS1 may be formed in the cylinder 141. A suction passage F, through which a refrigerant may be guided into the compression space CS1, may be formed in the piston 142. A suction valve 143 that opens and closes the suction passage may be disposed or provided on or at an end of the suction passage. A discharge valve 145a that opens and closes the compression space CS1 of the cylinder 141 may be disposed or provided on or at a front surface of the cylinder 141. One example of the cylinder 141 will be described with reference to
Referring to
The embodiments disclosed herein provides an effect of reducing a weight of the discharge unit by about 5 kg by changing the discharge unit 2b (see
That is, a valve assembly forming the discharge unit may include the valve plate 144 mounted to a head portion of the cylinder 141 (or one end of the cylinder 141), a suction valve 145b disposed or provided in or at a suction side of the valve plate 144 that opens and closes a suction port and the discharge valve 145a formed in a cantilever shape and disposed or provided in or at a discharge side of the valve plate 144 that opens and closes a discharge port.
A plurality of resonant springs 151 and 152 which induce a resonance motion of the piston 142 may be disposed or provided on both sides of the piston 142 in a moving direction thereof, respectively.
In the drawing, unexplained reference numeral 135 denotes a winding coil, 136 denotes a magnet, and CS2 denotes a discharge space.
In the related art reciprocating compressor, when power is applied to the coil 135 of the reciprocating motor 130, the mover 133 of the reciprocating motor 130 performs a reciprocating motion. The piston 142 coupled to the mover 133 then performs the reciprocating motion at a fast speed within the cylinder 141. During the reciprocating motion of the piston 142, a refrigerant is introduced into the inner space of the shell 110 through the suction pipe 111. The refrigerant introduced into the inner space of the shell 110 then flows into the compression space CS1 of the cylinder 141 along the suction passage of the piston 142. When the piston 142 moves forward, the refrigerant is discharged out of the compression space CS1 and then flows toward the condenser of the refrigerating cycle through the discharge pipe 112. This series of processes are repeatedly performed.
The outer stator 131 is formed by radially stacking a plurality of thin half stator cores, each of which may be formed in a shape like ‘’ to be symmetrical in a left and right direction, at both left and right sides of the winding coil 135.
As illustrated in
The discharge unit 501 included in the compressor according to this embodiment may be provided with a valve plate. The valve plate may be fixed to one end of the cylinder 502. At least one opening through which fluid compressed in the cylinder 503 may flow may be formed through the valve plate. In addition, the valve plate may be provided with a suction valve 511 and a discharge valve 521.
That is, the discharge unit 501 of the compressor according to this embodiment illustrated in
In addition, the discharge unit configured as the valve plate is lighter in weight than the discharge unit configured as the PEK valve. Therefore, noise generated due to a striking sound (crashing sound) between the discharge unit and the cylinder when the discharge unit is closed may be reduced. This may result in reducing a thickness of a shell covering the compressor and simplifying a material of a discharge cover. That is, a noise-reducing structure, such as the shell and a muffler, may be simplified in the linear compressor according to embodiments, thereby further reducing fabricating costs in comparison the related art linear compressor.
Meanwhile, as illustrated in
That is, the linear compressor executing the related art TDC control has used the discharge unit having the elastic member. Thus, the linear reciprocating motion of the piston is controlled by determining the collision time point between the discharge unit and the piston as a TDC arrival time point of the piston. However, in the linear compressor according to embodiments, unlike the related art linear compressor, the discharge unit in the shape of the valve plate is fixed to the one end of the cylinder 502. Accordingly, when the related art TDC control is executed, noise may be generated due to the collision between the piston 503 and the discharge unit, operation stability of the compressor may be lowered, and abrasion of the piston 503 and the discharge unit may occur.
Therefore, this specification proposes a compressor, capable of preventing collision between a piston and a discharge unit, in the linear compressor having the discharge unit in a shape of a valve plate, and a control method thereof. Referring to
As illustrated in
Unlike the grooves formed in the cylinders of the related art compressors illustrated in
Although not illustrated in
Although not illustrated in
The pressure changing unit 504 illustrated in
That is, the pressure applied to the piston or the variation rate of the pressure before the piston 503 moves over the pressure changing unit is different from the pressure applied to the piston or the variation rate of the pressure until before the piston reaches the VDS after moving over the pressure changing unit. In addition, the pressure changing unit 504 should be designed in a manner that a compression rate of a refrigerant or operation efficiency of the compressor cannot be substantially affected even though the pressure changing unit 504 changes the pressure applied to the piston or the variation rate of the pressure at a specific time point during the reciprocating motion of the piston.
Simultaneously, the pressure or the variation rate of the pressure changed by the pressure changing unit 504 should be high enough to be detected by the controller of the compressor. That is, the controller of the compressor may detect a time point at which the piston passes through the arranged position of the pressure changing unit 504 within the cylinder or a time point at which the pressure changing unit 504 changes the pressure applied to the piston or the pressure variation rate.
Referring to
When the piston 503 is brought into contact with the pressure changing unit 504 {circle around (2)}, the controller may determine that the pressure applied to the piston or the pressure variation rate changes. Also, when the piston 503 passes through the pressure changing unit 504 {circle around (3)}, the controller may determine that the pressure applied to the piston or the pressure variation rate changes.
In one embodiment, when the piston 503 is brought into contact with the discharge unit 501 {circle around (4)}, the controller may control the linear motor to switch the moving direction of the piston. In another embodiment, the controller may control the linear motor to switch the moving direction of the piston before the piston 503 is brought into contact with the discharge unit 501. In another embodiment, the controller may control the linear motor to switch the moving direction of the piston before the piston 503 reaches the VDS. Accordingly, the compressor according to embodiments may prevent the collision between the piston 503 and the discharge unit 501.
The VDS may be defined by the discharge unit 501 and the cylinder 502. That is, the VDS may be formed on at least a part of the discharge unit 501 facing the cylinder 502.
A first VDS VDS1 may be formed on a surface of the discharge unit 501 which is brought into contact with a portion of the suction valve 511. In this instance, the portion of the suction valve 511 may be a portion located in the cylinder 502.
A second VDS VDS2 may be formed on a surface where one surface of the valve plate of the discharge unit 501 and one end of the cylinder are brought into contact with each other. In addition, a third VDS VDS3 may also be formed on another surface of the valve plate of the discharge unit 501.
The controller may control the linear motor such that the piston 503 does not collide with the discharge unit 501, on the basis of one of the first to third VDSs VDS1, VDS2, and VDS3, according to a user setting.
A compressor according to one embodiment may include a controller that calculates a stroke of a piston using a motor current, generates a parameter associated with a position of the piston using the motor current and the calculated parameter, and controls a linear motor based on the generated parameter. In addition, the compressor may include a changing unit or device that changes a variation rate of the generated parameter before the piston reaches the VDS within a cylinder during a reciprocating motion.
Also, a compressor according to another embodiment may include a controller that calculates a phase difference between the motor current and the calculated stroke, and controls the linear motor based on the calculated phase difference. The controller may further include a changing unit or device that changes a variation rate of the calculated phase difference before the piston reaches the VDS during the reciprocating motion. The changing unit may be different from or the same as the pressure changing unit 504.
A controller of the compressor according to another embodiment may generate a preset or predetermined signal before the piston reaches the discharge unit when the piston moves close to the discharge unit or device during the reciprocating motion, in order to prevent collision between the piston and the discharge unit. In this instance, the controller may generate the preset signal using the detected motor voltage and motor current.
Also, the controller may determine that the piston is spaced apart from the discharge unit by a preset or predetermined distance while the piston moves close to the discharge unit, on the basis of a generation time point of the preset signal. Therefore, the controller may control the linear motor to switch a moving direction of the piston after a preset or predetermined time interval elapses from the generation time point of the preset signal.
A compressor according to another embodiment may include an additional volume unit or device disposed or provided within the cylinder to prevent the collision between the piston and the discharge unit. In this instance, the controller may determine whether the piston has passed through an arranged position of the additional volume unit within the cylinder, and control the linear motor based on the determination result.
Referring to
In this instance, the compressor according to embodiments may include a changing unit or device (not illustrated) that changes a variation rate of the generated parameter before the piston reaches the VDS within the cylinder during the reciprocating motion. That is, the changing unit may change the variation rate of the generated parameter before the piston reaches the VDS during the reciprocating motion.
In addition, the parameter may include at least one of pressure applied to the piston, a variable associated with a phase difference between the motor current and the stroke, a variable associated with a phase difference between the motor voltage and the stroke, or a gas constant Kg associated with the reciprocating motion of the piston. That is, the controller may detect the load F or the gas constant Kg, and detect the change in the variation rate of the load F or the gas constant Kg before the piston reaches the VDS.
In addition, the controller may detect a time point at which the variation rate of the parameter changes, and control the linear motor based on the detected time point such that the piston cannot reach or move over the VDS. When the piston 503 is brought into contact with the pressure changing unit 504 {circle around (2)}, the controller may detect the change in the variation rate of the load F or the gas constant Kg. In this instance, the load F is defined as pressure or force applied to the piston for each cycle.
Although not illustrated in
In one embodiment, the controller may detect a time point at which a variation rate of pressure applied to the piston changes, and control the linear motor to prevent the piston from reaching the VDS based on the detected time point. The controller may control the linear motor to switch a moving direction of the piston at a time point at which the variation rate of the pressure applied to the piston changes, or control the linear motor to switch the moving direction of the piston after a preset or predetermined time interval elapses from the detected time point.
The controller may calculate a stroke of the piston in real time, and detect a time point at which a variation rate of the pressure applied to the piston changes based on the calculated stroke. In this instance, the controller may determine that a time point at which a variation rate of the calculated stroke changes more than a preset or predetermined value corresponds to the time point at which the variation rate of the pressure applied to the piston changes.
Also, the controller may calculate a phase difference between the stroke of the piston and the motor current in real time, and detect a time point that the variation rate of the pressure applied to the piston changes based on the In the calculated phase difference. In this instance, the controller may determine that a time point at which a variation rate of the calculated phase difference changes more than a preset or predetermined value corresponds to the time point at which the variation rate of the pressure applied to the piston changes.
Also, the controller may calculate a phase difference between the stroke of the piston and the motor voltage in real time, and detect a time point at which the variation rate of the pressure applied to the piston changes based on the calculated phase difference. In this instance, the controller may determine that the a time point at which variation rate of the calculated phase difference changes more than a preset or predetermined value corresponds to the time point at which the variation rate of the pressure applied to the piston changes.
The preset value may change according to an output of the linear motor. For example, when the output of the motor increases, the controller may reset the preset value to a smaller value.
Although not illustrated, the linear compressor according to embodiments may further include an input unit or input that receives a user input associated with the preset time interval. The controller may reset the time interval based on the user input applied.
The controller may determine whether the piston has moved over the VDS on the basis of information related to the motor current, the motor voltage, and the stroke. In this instance, when it is determined that the piston has moved over the VDS, the controller may change the preset time interval. For example, the controller may reduce the preset time interval when it is determined that the piston has moved over the VDS.
The controller may determine whether the collision between the piston and the valve plate has occurred on the basis of information related to the motor current, the motor voltage, and the stroke. In this instance, the controller may change the preset time interval when it is determined that the collision between the piston and the valve plate has occurred. For example, the controller may reduce the preset time interval when it is determined that the piston has moved over the VDS.
In addition, the linear compressor according to embodiments may include a memory that stores information related to changes in the motor current, the motor voltage, and the stroke during the reciprocating motion of the piston. The memory may store information related to the changes for a time interval within which a reciprocating period of the piston is repeated by a predetermined number of times.
Accordingly, the controller may determine whether the piston collides with the valve plate using the information related to the change history of the motor voltage, the motor current, and the stroke.
The controller may calculate the stroke of the piston in real time, and detect the time point at which the variation rate of the pressure applied to the piston changes based on the calculated stroke. In this instance, the controller may determine that the time point at which the variation rate of the calculated stroke changes more than a preset or predetermined value corresponds to the time point at which the variation rate of the pressure applied to the piston changes.
Also, the controller may calculate the phase difference between the stroke and the motor current in real time and detect the time point at which the variation rate of the pressure applied to the piston changes based on the calculated phase difference. In this instance, the controller may determine that the time point at which the variation rate of the calculated phase difference changes more than a preset or predetermined value corresponds to the time point at which the variation rate of the pressure applied to the piston changes.
For example, the controller may detect a time point at which the variation rate of the phase difference is changed from a positive (+) value into a negative (−) value as the time point at which the variation rate of the pressure applied to the piston changes. As another example, the controller may detect a time point at which the variation rate of the phase difference is changed from a negative (−) value into a positive (+) value as the time point at which the variation rate of the pressure applied to the piston changes.
In one embodiment, the discharge unit 501 may be disposed or provided on or at one end of the cylinder 502. The pressure changing unit 504 may be disposed or provided between the one end of the cylinder, on which the discharge unit is disposed or provided, and another end of the cylinder. The pressure changing unit 504 may be disposed or provided between the one end of the cylinder 502 with the discharge unit 501 and a central portion of the cylinder. That is, the pressure changing unit 504 may be located adjacent to the one end at which the discharge unit is disposed or provided within the cylinder.
As illustrated in
As illustrated in
As illustrated in
Unlike the groove formed within the cylinder of the related art compressor described with reference to
The controller may detect that the variation rate of the load F or the gas constant Kg changes when the piston 503 enters the pressure changing unit 601 before reaching the VDS {circle around (2)}. In one embodiment, the pressure changing unit 601 may include the groove formed by the discharge unit and the one end of the cylinder.
Referring to
That is, referring to
The pressure changing unit 711 illustrated in
As illustrated in
The controller may calculate the gas constant Kg using the following Equation 2.
Where, I(jw) denotes a peak value of a current for one cycle, X(jw) denotes a peak value of a stroke for one cycle, a denotes a motor constant or counter electromotive force, θi,x denotes a phase difference between a current and a stroke, m denotes a moving mass of the piston, w denotes an operating frequency of a motor, Km denotes a mechanical spring constant.
Also, Equation 3 related to the gas constant Kg is derived by the above equation.
That is, the calculated gas constant Kg may be in proportion to the phase difference between the motor current and the stroke.
Therefore, the controller may detect based on the calculated gas constant Kg the time point at which the pressure applied to the piston or the variation rate of the pressure changes. That is, the controller may detect the gas constant Kg in real time and detect based on the calculated gas constant Kg the time point Tc at which the pressure applied to the piston or the pressure variation rate changes. In this instance, the controller may determine that a time point at which a variation rate of the calculated gas constant Kg changes more than a preset or predetermined value (801) corresponds to the time point Tc that the pressure applied to the piston or the pressure variation rate changes.
Referring to
Therefore, referring to
According to this control method, the TDC control for preventing the collision between the piston and the discharge unit of the linear compressor may be effectively executed even without using a separate sensor.
The linear compressor or its control device according to an embodiment may include a memory that stores information related to at least one transformation equation for calculating a parameter. The memory may be disposed or provided in the controller itself or installed in the compressor, separate from the controller. In addition, the controller may calculate the parameter associated with the movement or position of the piston in real time using the information related to the transformation equation stored in the memory and an estimated stroke value. For example, the parameter calculated by the transformation equation may form an inflection point at a time point at which the variation rate of the pressure applied to the piston changes before the piston reaches the VDS.
Referring to
One example of a transformation equation for calculating a parameter K″g illustrated in
Therefore, the controller may calculate the time point at which the pressure applied to the piston or the variation rate of the pressure changes on the basis of at least one of the calculated parameter K′g or parameter K″g. That is, the controller may calculate the parameter K′g or the parameter K″g in real time, and detect the time point at which the pressure applied to the piston or the variation rate of the pressure changes on the basis of the calculated parameter K′g or K″g. In this instance, the controller may determine that a time point (not illustrated) at which a variation rate of the calculated parameter K′g or K″g changes more than a preset or predetermined value corresponds to the time point at which the pressure applied to the piston or the variation rate of the pressure changes. For example, the time point at which the pressure applied to the piston or the pressure variation rate may correspond to the time point Tc at which the parameter K′g or K″g forms the inflection point.
The controller may compare a plurality of control variables transformed by a plurality of transformation equations when information related to the plurality of transformation equations is stored in the memory, and drive the motor based on the comparison result. For example, the controller may drive the motor to switch the moving direction of the piston when at least one of the plurality of control variables transformed by the plurality of transformation equations forms the inflection point.
In addition, the controller may detect the time point Tc at which the inflection point of the calculated parameter is formed, and control the motor to prevent the piston from colliding with the valve plate based on the detected time point Tc. The controller may control the motor to switch the moving direction of the piston after a lapse of a preset or predetermined time interval from the detected time point Tc. The preset time interval may be changed by the user.
The controller may detect the variation rate of the calculated parameter in real time, and determine that a time point (not illustrated) that the detected variation rate changes more than a preset value corresponds to the formation time point Tc of the inflection point.
However, the motor current and the motor voltage are measured at a predetermined period and the measured motor current and motor voltage do not change at a constant slope. Therefore, the controller may generate a trend line of the parameter.
Similarly, as illustrated in
Also, the controller may calculate a parameter associated with a position of the piston based on a detected motor current, generate a trend line associated with the calculated parameter, and control the linear motor based on the trend line information. A slope of the trend line may change before the piston reaches the VDS during the reciprocating motion.
The pressure changing unit 504 may include a groove formed within the cylinder. As illustrated in
For example, the first distance may be included in a range of about 1.5 mm to about 3 mm. In another example, the third distance may be included in a range of about 2 mm to about 4 mm. In another example, the second distance may be included in a range of about 0.3 mm to about 0.4 mm.
The memory may include information related to the groove. In this instance, the controller may detect the time point at which the pressure applied to the piston or the variation rate of the pressure changes, and control the motor to prevent the piston from reaching the VDS based on the stored information related to the groove. For example, the groove-related information may include at least one of information related to the width of the groove, information related to the depth of the groove and information related to a distance between the one end of the groove and the VDS.
Hereinafter, one embodiment of a pressure changing unit or device 601 of a compressor according to embodiments will be described with reference to
As illustrated in
The memory may store information related to the fifth and sixth distances r5 and r6 of the groove. Also, the memory may store information related to a fourth distance r4 by which one surface of a suction valve extends from the valve plate when the discharge unit is provided with the suction valve. In this instance, the controller may detect the time point at which the pressure applied to the piston or the variation rate of the pressure changes, and control the motor to prevent the piston from reaching the VDS based on the stored information related to the groove.
Hereinafter, one embodiment of a pressure changing unit or device 711 of a compressor according to embodiments will be described with reference to
As illustrated in
The memory may store information related to the seventh and eighth distances r7 and r8 of the groove. Also, the memory may store information related to a fourth distance r4 by which one surface of a suction valve extends from the valve plate when the discharge unit is provided with the suction valve. In this instance, the controller may detect the time point at which the pressure applied to the piston or the variation rate of the pressure changes, and control the motor to prevent the piston from reaching the VDS based on the stored information related to the groove.
In a linear compressor and a method for controlling a linear compressor according embodiments, collision between a piston and a discharge valve may be prevented so as to reduce noise generated in the linear compressor. Also, the prevention of the collision between the piston and the discharge valve may result in a reduction of abrasion of the piston and the discharge valve caused due to the collision, thereby extending a lifespan of mechanisms and components of the linear compressor.
Also, in the linear compressor and the method for controlling a linear compressor according to embodiments, fabricating costs of the discharge valve may be reduced, and fabricating costs of the linear compressor may be reduced accordingly. In addition, noise reduction and high-efficiency operation may simultaneously be obtained even without an addition of a separate sensor.
Embodiments disclosed herein provide a linear compressor capable of reducing noise by preventing collision between a piston and a discharge valve even without employing a separate sensor, and a method for controlling a linear compressor. Embodiments disclosed herein further provide a linear compressor capable of executing a high efficiency operation while reducing noise, and a method for controlling a linear compressor. Embodiments disclosed herein also provide a linear compressor capable of reducing noise generation and fabricating costs.
To achieve these and other advantages and in accordance with the purpose of this specification, as embodied and broadly described herein, there is provided a compressor that may include a piston performing a reciprocating motion within a cylinder, a linear motor to supply a driving force for the motion of the piston, a discharge unit or device to allow a refrigerant compressed in the cylinder to be discharged in response to the motion of the piston, and a pressure changing unit or device to change a variation rate of pressure applied to the piston before the piston reaches a virtual discharge surface (VDS) during the reciprocating motion, to prevent the piston from colliding with the discharge unit. The virtual discharge surface may be brought into contact with at least part of the discharge unit facing a compression space within the cylinder. In one embodiment disclosed herein, the compressor may further include a sensing unit or sensor to detect a motor voltage or motor current of the linear motor, and a controller to determine whether or not the variation rate of the pressure applied to the piston has changed using the detected motor voltage or motor current, and control the linear motor based on the determination result.
In one embodiment disclosed herein, the controller may detect a time point that the variation rate of the pressure applied to the piston changes, and control the linear motor to prevent the piston from reaching the discharge unit based on the detected time point. In one embodiment disclosed herein, the controller may calculate the variation rate of the pressure applied to the piston, form a trend line based on the calculated variation rate of the pressure, and determine that the variation rate of the pressure applied to the piston has changed when a slope of the formed trend line changes.
In one embodiment disclosed herein, the controller may control the linear motor to switch a moving direction of the piston after a lapse of a preset or predetermined time interval from the detected time point. In one embodiment disclosed herein, the controller may determine whether or not the piston has moved over the virtual discharge surface based on information related to the motor current or motor voltage and a stroke, and change the preset time interval when it is determined that the piston has moved over the virtual discharge surface.
In one embodiment disclosed herein, the compressor may further include a memory to store information related to changes in the motor current, the motor voltage, and the stroke during the reciprocating motion of the piston, and the controller may determine whether or not the piston has moved over the virtual discharge surface on the basis of the changes.
In one embodiment disclosed herein, the discharge unit may be disposed on or at one end of the cylinder, and the pressure changing unit may be disposed or provided between the one end of the cylinder having the discharge unit disposed thereon and another end of the cylinder. In one embodiment disclosed herein, the pressure changing unit may be disposed or provided between the one end of the cylinder having the discharge unit disposed thereon and a central portion of the cylinder.
In one embodiment disclosed herein, the pressure changing unit may include a groove spaced apart from at least part of the discharge unit and formed on an inner wall of the cylinder. In one embodiment disclosed herein, the pressure changing unit may include a groove formed by the discharge unit and the one end of the cylinder.
In one embodiment disclosed herein, the discharge unit may include a discharge valve to discharge a refrigerant compressed in the cylinder therethrough, and a valve plate to support the discharge valve. The valve plate may be fixed to the one end of the cylinder.
In one embodiment disclosed herein, the pressure changing unit may include a groove formed by the valve plate at an outside of the cylinder. In one embodiment disclosed herein, the discharge unit may further include a suction valve to suck a refrigerant into the cylinder therethrough, and the valve plate may support the suction valve. In one embodiment disclosed herein, the compressor may further include a suction unit disposed on an end of the piston to suck the refrigerant into the cylinder therethrough.
A compressor according to another embodiment may include a piston performing a reciprocating motion within a cylinder, a linear motor to supply a driving force for the motion of the piston, a discharge unit or device disposed or provided on one end of the cylinder to allow a refrigerant compressed in the cylinder to be discharged in response to the motion of the piston, a sensing unit or sensor to detect a motor current of the linear motor, a controller to calculate a stroke of the piston using the detected motor current, generate a parameter associated with a position of the piston using the motor current and the calculated stroke, and control the linear motor based on the generated parameter, and a changing unit or device to change a variation rate of the generated parameter before the piston reaches a virtual discharge surface (VDS) within the cylinder during the reciprocating motion. The virtual discharge surface may be formed by at least part of the discharge unit facing the cylinder. In one embodiment disclosed herein, the generated parameter may be a gas constant Kg associated with the reciprocating motion of the piston.
In one embodiment disclosed herein, the controller may detect a time point that the variation rate of the parameter changes, and control the linear motor to switch a moving direction of the piston after a lapse of a preset or predetermined time interval from the detected time point, to prevent collision between the piston and the discharge unit. In one embodiment disclosed herein, the controller may control the linear motor to switch a moving direction of the piston after a lapse of a preset or predetermined time interval from the detected time point.
A compressor according to another embodiment may include a piston performing a reciprocating motion within a cylinder, a linear motor to supply a driving force for the motion of the piston, a discharge unit or device disposed or provided on or at one end of the cylinder to allow a refrigerant compressed in the cylinder to be discharged in response to the motion of the piston, a sensing unit or sensor to detect a motor current of the linear motor, a controller to calculate a stroke of the piston using the detected motor current, calculate a phase difference between the motor current and the calculated stroke, and control the linear motor based on the calculated phase difference, and a changing unit or device to change a variation rate of the calculated phase difference before the piston reaches a virtual discharge surface (VDS) during the reciprocating motion. The virtual discharge surface may be formed on at least part of the discharge unit facing the cylinder.
In one embodiment disclosed herein, the controller may detect a time point that the variation rate of the calculated phase difference changes, and control the linear motor to prevent the piston from colliding with the discharge unit based on the detected time point. In one embodiment disclosed herein, the controller may control the linear motor to switch a moving distance of the piston after a lapse of a preset or predetermined time interval from the detected time point.
A compressor according to another embodiment disclosed herein may include a piston performing a reciprocating motion within a cylinder, a linear motor to supply a driving force for the motion of the piston, a discharge unit or device to allow a refrigerant compressed in the cylinder to be discharged in response to the motion of the piston, and a controller to control the linear motor. The controller may generate a preset or predetermined signal before the piston reaches the discharge unit when the piston moves close to the discharge unit during the reciprocating motion, to prevent collision between the piston and the discharge unit.
In one embodiment disclosed herein, the compressor may further include a sensing unit or sensor to detect a motor voltage or motor current of the linear motor, and the controller may generate the preset signal using the detected motor voltage or motor current. In one embodiment disclosed herein, the controller may determine that the piston is spaced apart from the discharge unit by a preset or predetermined distance while moving close to the discharge unit, on the basis of a time point that the preset signal is generated. In one embodiment disclosed herein, the controller may control the linear motor to switch the moving direction of the piston after a lapse of a preset or predetermined time interval from the generation time point of the preset signal.
A compressor according to another embodiment disclosed herein may include a piston performing a reciprocating motion within a cylinder, a linear motor to supply a driving force for the motion of the piston, a discharge unit or device to discharge a refrigerant compressed within the cylinder therethrough in response to the motion of the piston, an additional volume unit or device provided within the cylinder to prevent collision between the piston and the discharge unit, a sensing unit or sensor to detect a motor voltage or motor current of the linear motor, and a controller to determine whether or not the piston has passed through an arranged position of the additional volume unit within the cylinder using the detected motor voltage or motor current, and control the linear motor based on the determination result. In one embodiment disclosed herein, a compression space of the cylinder may include a first volume formed by a surface brought into contact with at least part of an inner wall of the cylinder and the discharge unit, and a second volume formed by the additional volume unit.
In one embodiment disclosed herein, the additional volume unit may change a load applied to the piston when the piston passes through the arranged position of the additional volume unit within the cylinder during the reciprocating motion. In one embodiment disclosed herein, the controller may control the linear motor to switch the moving direction of the piston after a lapse of a preset or predetermined time interval from a time point that the piston passes through the arranged position of the additional volume unit within the cylinder.
Further scope of applicability will become more apparent from the detailed description given hereinafter. However, it should be understood that the detailed description and specific examples, while indicating embodiments, are given by way of illustration only, since various changes and modifications within the spirit and scope will become apparent to those skilled in the art from the detailed description.
It will be apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit or scope. Thus, it is intended that embodiments cover modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.
Any reference in this specification to “one embodiment,” “an embodiment,” “example embodiment,” etc., means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with any embodiment, it is submitted that it is within the purview of one skilled in the art to effect such feature, structure, or characteristic in connection with other ones of the embodiments.
Although embodiments have been described with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More particularly, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, alternative uses will also be apparent to those skilled in the art.
Number | Date | Country | Kind |
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10-2015-0150482 | Oct 2015 | KR | national |