JP2009133571A - Refrigeration device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the non-continuation of refrigerant filling operation caused by a fact that an expansion valve is brought into a closed state in a refrigeration device equipped with a refrigerant circuit provided with an opening-variable expansion valve. <P>SOLUTION: The refrigerant device is composed so that a valve control means 53 for controlling an opening of the expansion valve 18 carries out the determination operation for determining whether or not the expansion valve 18 is in a closed state on the basis of the state of a low pressure side refrigerant between the expansion valve 18 and a compressor 30 in a state that an opening command value is equal to a lower limit command value during the refrigerant filling operation of filling a refrigerant in the refrigerant circuit 20 while carrying out a refrigerating cycle so that a user side heat exchanger 37 in the refrigerant circuit 20 is operated as an evaporator. The valve control means 53 is composed to correct the lower limit command value to a larger value when it is determined that the expansion valve 18 is in the closed state in the determination operation. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a refrigeration apparatus including a refrigerant circuit provided with an expansion valve having a variable opening.

  Conventionally, a refrigeration apparatus including a refrigerant circuit provided with an expansion valve having a variable opening is known. Patent Document 1 discloses an air conditioner as this type of refrigeration apparatus. This air conditioner includes a superheat degree control device. The control unit of the superheat degree control device calculates the difference between the inlet temperature of the outdoor heat exchanger and the outlet temperature of the outdoor heat exchanger during heating as the superheat degree of the outlet of the outdoor heat exchanger, and calculates the calculated superheat degree and the target superheat. The difference from the degree is calculated as a deviation E. And the valve control part of a superheat degree control apparatus controls the opening degree of an electric expansion valve so that the deviation E may be set to zero.

In addition, this type of refrigeration apparatus includes a refrigerant charging operation in which a refrigerant circuit is charged with a refrigerant while performing a refrigeration cycle so that the use side heat exchanger operates as an evaporator in the refrigerant circuit. In the refrigerant charging operation, for example, the amount of refrigerant charged is managed while observing the degree of supercooling of the liquid refrigerant condensed in the heat source side heat exchanger, and the use side heat exchange is performed to accurately grasp the amount of refrigerant charged. The opening degree of the expansion valve is controlled so that the superheat degree of the refrigerant at the outlet of the use side heat exchanger becomes a predetermined target superheat degree so that the refrigerant between the compressor and the suction side of the compressor is in a gas state. The The opening command value output to the expansion valve when adjusting the opening is adjusted within a range equal to or greater than a predetermined lower limit command value.
Japanese Patent Laid-Open No. 7-225058

  By the way, variable opening degree expansion valves used in this type of refrigeration apparatus have individual differences in opening degree, and even when the opening degree command value inputted is the same value, the actual opening degree varies. For this reason, the opening command value when the expansion valve changes from the closed state to the open state differs depending on the expansion valve, and depending on the expansion valve, the opening command value is opened when the opening command value becomes equal to the lower limit command value. Some are closed.

  On the other hand, in a conventional refrigeration apparatus that performs a refrigerant charging operation, the expansion valve is opened during the refrigerant charging operation, for example, when the temperature of the air sent to the use side heat exchanger is lower than the normal operating state. As the degree is narrowed, the opening command value of the expansion valve may become equal to the lower limit command value. Therefore, depending on the expansion valve to be used, the expansion valve may be in a closed state, and refrigerant may not pass through the expansion valve and the refrigerant charging operation may not be continued.

  The present invention has been made in view of the above points, and an object of the present invention is to charge refrigerant due to the expansion valve being closed in a refrigeration apparatus having a refrigerant circuit provided with an expansion valve having a variable opening degree. The purpose is to prevent the operation from being continued.

  The first invention includes a compressor (30), a use side heat exchanger (37), and an expansion valve (18) with a variable opening for adjusting the refrigerant flow rate of the use side heat exchanger (37). And a valve control means (53) for controlling the opening degree of the expansion valve (18). In the refrigerant circuit (20), the use side heat exchanger (37) is an evaporator. During the refrigerant charging operation in which the refrigerant circuit (20) is charged with the refrigerant while performing the refrigeration cycle so as to operate as described above, the valve control means (53) causes the refrigerant at the outlet of the use side heat exchanger (37) to overheat. The opening degree of the expansion valve (18) is controlled by outputting an opening degree command value larger than a predetermined lower limit command value to the expansion valve (18) so that the degree becomes a predetermined target superheat degree. For refrigeration equipment.

  The refrigeration apparatus includes the expansion valve (18) and the compressor (30) in a state where the valve control means (53) has the opening command value equal to the lower limit command value during the refrigerant charging operation. And determining whether the expansion valve (18) is in a closed state based on the state of the low-pressure side refrigerant with respect to the suction side, and the expansion valve (18) is closed in the determination operation When it is determined that the value is lower, the lower limit command value is corrected to a larger value.

  In the first invention, the valve control means (53) is an expansion valve based on the state of the low-pressure side refrigerant (for example, pressure or temperature) in a state where the opening degree command value is equal to the lower limit command value during the refrigerant charging operation. A determination operation for determining whether (18) is in the closed state is performed. The valve control means (53) corrects the lower limit command value to a large value when it is determined in the determination operation that the expansion valve (18) is in the closed state. When the lower limit command value is corrected to a large value, the opening command value is also changed to a large value accordingly, so that the expansion valve (18) is adjusted to the open side. In the first aspect of the invention, when it is determined that the expansion valve (18) is in the closed state in a state where the opening degree command value is equal to the lower limit command value during the refrigerant charging operation, the expansion valve (18) Is adjusted to the opening side.

  In a second aspect based on the first aspect, the refrigerant circuit (20) includes a plurality of utilization side circuits (17) provided with the utilization side heat exchanger (37) and the expansion valve (18). While connected in parallel, the valve control means (53) is in a state where the opening command values of the expansion valves (18) of all the use side circuits (17) are equal to the lower limit command value during the refrigerant charging operation. The above-described determination operation is performed only at, and the lower limit command value is corrected when it is determined by the determination operation that the expansion valves (18) of all the use side circuits (17) are closed.

  In the second invention, the determination operation is performed only when the opening command values of the expansion valves (18) of all the use side circuits (17) are equal to the lower limit command value during the refrigerant charging operation. And when it determines with the expansion operation | movement (18) of all the utilization side circuits (17) being a closed state by the determination operation | movement, a lower limit command value is correct | amended to a big value. On the other hand, when there is an expansion valve (18) whose opening command value is larger than the lower limit command value, the determination operation is not performed, and the lower limit command value is not corrected.

  According to a third aspect of the present invention, in the first or second aspect of the present invention, the valve control means (53) has a continuation time in which the pressure of the low-pressure side refrigerant is below a predetermined first low-pressure reference value for a predetermined determination time. And at least one of a second condition in which the pressure of the low-pressure side refrigerant falls below a predetermined second low-pressure reference value that is smaller than the first low-pressure reference value is satisfied in the determination operation. It is determined that the expansion valve (18) is closed.

  In the third invention, it is determined that the expansion valve (18) is in the closed state when at least one of the first condition and the second condition is satisfied in the determination operation. The first condition is a condition that the duration of the state where the pressure of the low-pressure side refrigerant is lower than a predetermined first low-pressure reference value reaches a predetermined determination time. The second condition is a condition that the pressure of the low-pressure side refrigerant falls below a predetermined second low-pressure reference value that is smaller than the first low-pressure reference value. In the third aspect of the invention, the determination as to whether or not the expansion valve (18) is closed is made using two conditions with different low pressure reference values.

  According to a fourth invention, in any one of the first to third inventions, after the valve control means (53) corrects the lower limit command value in the refrigerant charging operation, the lower limit command value is corrected. The determination operation is performed after waiting for a later elapsed time to reach a predetermined reference time.

  In the fourth invention, when it is determined that the expansion valve (18) is closed, the lower limit command value is corrected, and the opening degree command value is changed to a value equal to or greater than the corrected lower limit command value to expand the expansion valve (18). Is adjusted to the opening side. After the lower limit command value is corrected, the determination operation is performed after a predetermined reference time has elapsed. That is, in the fourth aspect of the invention, the determination operation is performed after waiting for a certain amount of time after the expansion valve (18) is adjusted to the open side.

  According to a fifth invention, in any one of the first to fourth inventions, the valve control means (53) corrects the lower limit command value within a predetermined upper limit value or less during the refrigerant charging operation. Do.

  In the fifth invention, the lower limit command value is corrected within a range equal to or lower than the upper limit value. That is, the lower limit command value is corrected so as not to exceed the predetermined upper limit value.

  In the present invention, when it is determined that the expansion valve (18) is in the closed state while the opening degree command value is equal to the lower limit command value during the refrigerant charging operation, the lower limit command value is corrected to a larger value. As a result, the expansion valve (18) is adjusted to the open side. That is, when it is detected that the expansion valve (18) is in a closed state when the opening command value becomes equal to the lower limit command value, the expansion valve (18) is adjusted to the open side. For this reason, since the refrigerant is adjusted so that it can pass through the expansion valve (18), it is possible to prevent the refrigerant charging operation from being continued due to the expansion valve (18) being closed. Can do.

  In the third aspect of the invention, the determination as to whether or not the expansion valve (18) is closed is made using two conditions with different low-pressure reference values. In the first condition out of the two conditions, the duration of the state where the pressure of the low-pressure side refrigerant is lower than the low-pressure reference value is used in the determination. For this reason, since it is possible to determine whether or not the expansion valve (18) is closed more accurately than in the case where it is determined whether or not the expansion valve (18) is closed under only one condition, the expansion valve It can be further reliably prevented that the refrigerant charging operation cannot be continued due to the closed state (18).

  In the fourth aspect of the invention, the determination operation is performed after a certain amount of time has elapsed since the expansion valve (18) was adjusted to the open side. Here, when the expansion valve (18) changes from the closed state to the open state by correcting the lower limit command value to a large value, the state of the low-pressure refrigerant begins to change, but the expansion valve (18) changes to the open state. After that, a certain amount of time is required until the state of the low-pressure side refrigerant is stabilized. For this reason, when the determination operation is performed immediately after adjusting the expansion valve (18) to the open side, the state of the low-pressure side refrigerant is not stable, so that the expansion valve (18) has been opened. The lower limit command value may be corrected to a larger value without noticing. In contrast, in the fourth aspect of the invention, the determination operation is performed after waiting for the state of the low-pressure side refrigerant to stabilize after the expansion valve (18) changes to the open state. Therefore, it is possible to accurately set the lower limit command value without erroneously determining that the expansion valve (18) is in the closed state even though the expansion valve (18) is in the open state. it can.

  In the fifth aspect of the invention, the lower limit command value is corrected within the range of the upper limit value or less. Here, as described above, the opening command value when the expansion valve (18) changes from the closed state to the open state varies depending on the expansion valve (18). However, the range of variation in the opening command value when the expansion valve (18) is opened is determined to some extent. That is, even if the expansion valve (18) has a large variation amount, it always opens when the lower limit command value is increased to some extent. In the fifth aspect of the invention, in consideration of the above, the lower limit command value is corrected within a range equal to or lower than the upper limit value. Therefore, it is possible to prevent the lower limit command value from being corrected to a large value exceeding the upper limit value due to erroneous determination or the like, for example, although the expansion valve (18) is in the open state.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  An embodiment of the present invention will be described. In the following, first, the refrigeration apparatus (10) to which the refrigerant charging method according to the present invention is applied will be described, and then the refrigerant charging method according to the present invention will be described.

<Overall configuration of refrigeration equipment>
The refrigeration apparatus (10) according to the present embodiment is an air conditioner (10) that adjusts the temperature of an indoor space. As shown in FIG. 1, the refrigeration apparatus (10) includes one outdoor unit (11) and a plurality of (for example, three) indoor units (13). The outdoor unit (11) constitutes a heat source unit, and the indoor unit (13) constitutes a utilization unit.

  The refrigeration apparatus (10) includes a refrigerant circuit (20) filled with a refrigerant. The refrigerant circuit (20) includes an outdoor circuit (21) accommodated in the outdoor unit (11), and an indoor circuit (17) accommodated in each indoor unit (13). It is constituted by being connected by the side connection pipe (24). The outdoor circuit (21) constitutes a heat source side circuit, and each indoor circuit (17) constitutes a use side circuit. The plurality of indoor circuits (17) are connected in parallel to each other. In the refrigerant circuit (20), a vapor compression refrigeration cycle is performed by circulating the refrigerant.

《Outdoor circuit configuration》
The outdoor circuit (21) is connected to the liquid side shutoff valve (25) provided at the liquid side end with the liquid side connection pipe (23) and to the gas side shutoff valve (26) provided at the gas side end. Connecting pipe (24) is connected. The outdoor circuit (21) is connected to a compressor (30), an outdoor heat exchanger (34) that is a heat source side heat exchanger, an outdoor expansion valve (36), and a four-way switching valve (33).

  The compressor (30) is configured as, for example, a fully sealed high-pressure dome type scroll compressor. Electric power is supplied to the compressor (30) via an inverter. The compressor (30) is configured such that the operating capacity can be changed in a plurality of stages by changing the rotation speed of the electric motor by changing the output frequency of the inverter. The discharge side of the compressor (30) is connected to the first port (P1) of the four-way switching valve (33). The suction side of the compressor (30) is connected to the third port (P3) of the four-way switching valve (33).

  The outdoor heat exchanger (34) is configured as a cross-fin type fin-and-tube heat exchanger. An outdoor fan (12) for sending outdoor air to the outdoor heat exchanger (34) is provided in the vicinity of the outdoor heat exchanger (34). In the outdoor heat exchanger (34), heat is exchanged between the outdoor air and the refrigerant. One end of the outdoor heat exchanger (34) is connected to the fourth port (P4) of the four-way switching valve (33). The other end of the outdoor heat exchanger (34) is connected to the liquid side closing valve (25). The second port (P2) of the four-way switching valve (33) is connected to the gas side shut-off valve (26).

  An outdoor expansion valve (36) is provided between the liquid side closing valve (25) and the outdoor heat exchanger (34). The outdoor expansion valve (36) is an electric expansion valve in which a needle (76) that is a valve element is driven by a pulse motor (75). The opening degree of the outdoor expansion valve (36) is adjusted according to the magnitude of the control pulse (opening command value) of the pulse signal output from the valve control unit (53) described later.

  In the four-way selector valve (33), the first port (P1) and the second port (P2) communicate with each other, and the third port (P3) and the fourth port (P4) communicate with each other (solid line in FIG. 1). 1), a state in which the first port (P1) and the fourth port (P4) communicate with each other, and a state in which the second port (P2) and the third port (P3) communicate with each other (shown by a broken line in FIG. 1). The second state shown in FIG.

  The liquid side closing valve (25) is provided with a liquid side service port (27). On the other hand, the gas side shut-off valve (26) is provided with a gas side service port (28). These service ports (27, 28) are used when the refrigerant circuit (20) is filled with refrigerant or when the refrigerant in the refrigerant circuit (20) is collected, and are closed during the cooling operation and the heating operation.

  A discharge pressure sensor (31) for detecting the pressure of the high-pressure side refrigerant discharged from the compressor (30) is provided between the discharge side of the compressor (30) and the four-way switching valve (33). Between the suction side of the compressor (30) and the four-way switching valve (33), a suction pressure sensor (32) for detecting the pressure of the low-pressure side refrigerant sucked into the compressor (30) is provided. The measured values of these sensors (31, 32) are input to the controller (50).

《Indoor circuit configuration》
Each indoor circuit (17) has a liquid side connecting pipe (23) connected to the liquid side end and a gas side connecting pipe (24) connected to the gas side end. In each indoor circuit (17), from the gas side end toward the liquid side end, the indoor heat exchanger (37) that is the use side heat exchanger and the indoor that adjusts the refrigerant flow rate of the indoor heat exchanger (37) An expansion valve (18) is provided.

  The indoor heat exchanger (37) is a cross-fin type fin-and-tube heat exchanger. An indoor fan (14) for sending room air to the indoor heat exchanger (37) is provided in the vicinity of the indoor heat exchanger (37). In the indoor heat exchanger (37), heat is exchanged between the indoor air and the refrigerant.

  The indoor expansion valve (18) is an electric expansion valve in which a needle (76) that is a valve element is driven by a pulse motor (75). The opening degree of the indoor expansion valve (18) is adjusted according to the magnitude of the control pulse (opening command value) of the pulse signal output from the valve control unit (53) described later. Details of the indoor expansion valve (18) will be described later.

  Moreover, the liquid side temperature sensor (38) which detects the temperature of the refrigerant | coolant which distribute | circulates the liquid side of an indoor heat exchanger (37) is provided in the liquid side of the indoor heat exchanger (37). Moreover, the gas side temperature sensor (39) which detects the temperature of the refrigerant | coolant which distribute | circulates the gas side of an indoor heat exchanger (37) is provided in the gas side of an indoor heat exchanger (37). A suction temperature sensor (40) for measuring the temperature of air flowing into the indoor heat exchanger (37) is provided in the vicinity of the indoor heat exchanger (37). The measured values of these sensors (38 to 40) are input to the controller (50).

<Structure of expansion valve>
Both the outdoor expansion valve (36) and the indoor expansion valve (18) are direct-acting electric expansion valves. Here, the indoor expansion valve (18) will be described with reference to FIG. The outdoor expansion valve (36) has the same structure as the indoor expansion valve (18).

  In the indoor expansion valve (18), a solenoid (72) as a stator disposed on the outer peripheral side of a cylindrical motor casing (71), and a rotor (a rotor as a rotor located in the casing (71)) A pulse motor (75) is constituted by the magnet (74) provided in 73). The indoor expansion valve (18) is configured to move up and down a needle (76) provided with a valve portion (76a) at the tip according to the rotation of the rotor (73).

  The rotor (73) includes a cylindrical bush (77) and a magnet (74) disposed on the outer peripheral side thereof. The bush (77) has a hole (77a) that opens downward near the center of rotation. The hole (77a) is a female screw having a thread formed on its inner peripheral surface. In the hole (77a), a needle (76) whose upper end is fixed to the rotor (73) is disposed so as to extend downward.

  A columnar main body (78) is integrally provided below the motor casing (71). Inside the main body (78), holes (78a, 78b) as flow passages that open to the side and downward are formed so as to be orthogonal to each other. The main body portion (78) is connected to the hole portions (78a, 78b), respectively, so as to form first and second pipes (85, 86). ) Is connected. A valve seat (81) for receiving the valve portion (76a) is provided in the hole portion (78b) to which the second joint (80) is connected.

  Further, a hole (78c) extending upward from the hole (78b) provided with the valve seat (81) is also formed in the main body (78). A cylindrical member (82) extending upward is disposed above the main body (78) so as to communicate with the internal space of the hole (78c). A threaded portion is formed on the outer peripheral surface of the cylindrical member (82) and is screwed into the hole (77a) of the rotor (73). Thus, when the rotor (73) rotates, the rotor (73) moves up and down with respect to the main body (78) fixed to the motor casing (71).

  Inside the cylindrical member (82), the needle (76) is arranged in such a posture that the upper end side is fixed to the rotor (73) and extends downward in the hole (77a). The needle (76) is also inserted into the hole (78c) of the main body (78) communicating with the internal space of the cylindrical member (82). The valve portion (76a) at the lower end of the needle (76) is a portion where the hole portions (78a, 78b) of the main body portion (78) are orthogonal to each other (that is, the communication portion (87)). Opposite the provided valve seat (81). Thus, as described above, when the rotor (73) moves up and down, the needle (76) moves up and down in the cylindrical member (82) and the hole (78c) of the main body (78) accordingly. The valve portion (76a) at the lower end of the needle (76) moves up and down with respect to the valve seat (81) (moves in the longitudinal direction of the second conduit), thereby opening and closing the indoor expansion valve (18). Operation will be performed.

  The indoor expansion valve (18) used in the refrigeration apparatus (10) is a product in which the maximum value of the control pulse (EV) is EV_max pulse (for example, EV_max = 2000). As shown in FIG. 3, in this product, the flow characteristic representing the relationship between the control pulse (EV) and the passage flow rate of the indoor expansion valve (18) has a variation in the range from the characteristic line A to the characteristic line C. The characteristic line A represents the flow rate characteristic of the indoor expansion valve (18) in which the passage flow rate of the indoor expansion valve (18) is maximum in this product. A characteristic line B represents a flow rate characteristic of the indoor expansion valve (18) in which the passage flow rate of the indoor expansion valve (18) is an average value in this product. The characteristic line C represents the flow rate characteristic of the indoor expansion valve (18) in which the passage flow rate of the indoor expansion valve (18) is minimized in this product. In addition, in the standard of the expansion valve (13), the flow rate when fully opened is determined in accordance with conditions (for example, 30 ° C.) in which the set temperature in the refrigerator is relatively high.

-Driving action-
Next, the operation of the refrigeration apparatus (10) will be described. The refrigeration apparatus (10) is configured to be able to switch between a cooling operation and a heating operation by switching the four-way switching valve (33). The cooling operation and the heating operation are normal operations for adjusting the temperature of the room. In addition to the normal operation, the refrigeration apparatus (10) is configured to be able to execute a refrigerant charging operation performed when the refrigerant circuit (20) is charged with the refrigerant.

<Cooling operation>
In the cooling operation, the four-way switching valve (33) is set to the second state. When the compressor (30) is operated in this state, the vapor compression refrigeration cycle in which the outdoor heat exchanger (34) serves as a condenser and each indoor heat exchanger (37) serves as an evaporator in the refrigerant circuit (20). Is done.

  Specifically, the refrigerant discharged from the compressor (30) dissipates heat to the outdoor air and condenses in the outdoor heat exchanger (34). The refrigerant condensed in the outdoor heat exchanger (34) is distributed to each indoor circuit (17). In each indoor circuit (17), the refrigerant is depressurized by the indoor expansion valve (18), and the depressurized refrigerant absorbs heat from the indoor air in the indoor heat exchanger (37) and evaporates. Thereby, the air cooled with the indoor heat exchanger (37) is supplied indoors. The refrigerant evaporated in each indoor heat exchanger (37) joins in the liquid side connecting pipe (23), and then is sucked into the compressor (30) and compressed.

<Heating operation>
In the heating operation, the four-way switching valve (33) is set to the first state. When the compressor (30) is operated in this state, the vapor compression refrigeration cycle in which the outdoor heat exchanger (34) serves as an evaporator and each indoor heat exchanger (37) serves as a condenser in the refrigerant circuit (20). Is done.

  Specifically, the refrigerant discharged from the compressor (30) is distributed to each indoor circuit (17). In each indoor circuit (17), the refrigerant dissipates heat to the indoor air and condenses in the indoor heat exchanger (37). Thereby, the air heated with the indoor heat exchanger (37) is supplied indoors. The refrigerant condensed in each indoor heat exchanger (37) is decompressed by each indoor expansion valve (18), joins in the liquid side communication pipe (23), and flows into the outdoor circuit (21). In the outdoor circuit (21), the refrigerant absorbs heat from the outdoor air and evaporates in the outdoor heat exchanger (34). The refrigerant evaporated in the outdoor heat exchanger (34) is sucked into the compressor (30) and compressed.

<Refrigerant charging operation>
The operation of the refrigerant charging operation is exactly the same as that of the cooling operation. In the refrigerant charging operation, the compressor (30) is operated in a state where the cylinder filled with the refrigerant is connected to the liquid side service port (27) and the gas side service port (28) via the refrigerant hose. The four-way selector valve (33) is set to the second state. In the refrigerant circuit (20), a vapor compression refrigeration cycle is performed in which the outdoor heat exchanger (34) serves as a condenser and each indoor heat exchanger (37) serves as an evaporator.

  In the refrigerant charging operation, the amount of refrigerant charged is managed while observing the degree of supercooling of the liquid refrigerant condensed in the outdoor heat exchanger (34), and indoor heat exchange is performed to accurately grasp the amount of refrigerant charged. So that the refrigerant between the compressor (37) and the suction side of the compressor (30) is in a gas state, the superheat degree of the refrigerant at the outlet of each indoor heat exchanger (37) is a predetermined target superheat degree (for example, 5 The opening degree of each indoor expansion valve (18) is controlled so as to be at (° C.).

-Controller configuration-
The refrigeration apparatus (10) of the present embodiment is provided with a controller (50) for controlling the operation of the refrigeration apparatus (10). The controller (50) is configured to control the operation of the outdoor unit (11) and the indoor unit (13). The controller (50) may be composed of a control board of the outdoor unit (11) and a control board of each indoor unit (13) that can communicate with the control board of the outdoor unit (11).

  In the present embodiment, the controller (50) includes a valve control unit (53) that is a valve control means. The valve control unit (53) is configured such that the superheat degree (SH) of the gas refrigerant flowing out of the indoor heat exchanger (37) is a predetermined target superheat degree for each indoor unit (13) during the cooling operation and the refrigerant charging operation. Superheat control is performed to control the opening of the indoor expansion valve (18) so as to be (for example, 5 ° C.). Further, the valve control unit (53) is configured such that the supercooling degree (SC) of the liquid refrigerant flowing out from each indoor heat exchanger (37) is a predetermined target supercooling degree with respect to each indoor unit (13) during the heating operation. Sub-cool control is performed to control the opening of each indoor expansion valve (18) so as to be (for example, 5 ° C.).

  Specifically, in the superheat control, the valve control unit (53) calculates the difference between the measured value of the gas side temperature sensor (39) and the measured value of the liquid side temperature sensor (38) as an indoor heat exchanger (37). It is detected as the degree of superheat (SH) of the refrigerant flowing out of the tank. Then, the valve control unit (53) determines the control pulse (EV) of the indoor expansion valve (18) so that the detected degree of superheat (SH) approaches the target degree of superheat, and determines the determined control pulse (EV) Is output to the pulse motor (75) of the indoor expansion valve (18). The valve control unit (53) increases the control pulse (EV) when the detected superheat degree (SH) is larger than the target superheat degree. On the other hand, the valve control unit (53) decreases the control pulse (EV) when the detected superheat degree (SH) is smaller than the target superheat degree.

  On the other hand, in the subcool control, the valve control unit (53) causes the difference between the measured value of the gas side temperature sensor (39) and the measured value of the liquid side temperature sensor (38) to flow out from the indoor heat exchanger (37). Detected as the degree of refrigerant supercooling (SC). Then, the valve control unit (53) determines the control pulse (EV) of the indoor expansion valve (18) so that the detected degree of supercooling (SC) approaches the target degree of supercooling, and determines the determined control pulse ( EV) pulse signal is output to the pulse motor (75) of the indoor expansion valve (18). The valve control unit (53) increases the control pulse (EV) when the detected degree of supercooling (SC) is larger than the target degree of supercooling. On the other hand, the valve control unit (53) decreases the control pulse (EV) when the detected degree of supercooling (SC) is smaller than the target degree of supercooling.

  In the valve controller (53), a lower limit command value (EVL) that is a lower limit value of the control pulse is set in advance. In the valve control unit (53), the control pulse (EV) is determined in a range not less than the lower limit command value (EVL) and not more than the maximum value (EV_max).

  Moreover, in this embodiment, as shown in FIG. 1, the valve control part (53) is provided with the lower limit correction | amendment part (54). The lower limit correction unit (54) is configured to perform a lower limit correction operation for correcting the lower limit command value (EVL) during the refrigerant charging operation. Details of the lower limit correction operation will be described later. The lower limit correction unit (54) may be configured to perform the lower limit correction operation even during normal operation.

-Controller operation-
The operation of the controller (50) during the refrigerant charging operation will be described below with reference to FIG.

  First, in the refrigerant charging operation, the controller (50) sets the four-way switching valve (33) to the second state and activates the compressor (30), the outdoor fan (12), and each indoor fan (14). Start by letting. At that time, the valve control unit (53) outputs a pulse signal having a predetermined initial value (for example, 160 pulses) as a control pulse (EV) to each indoor expansion valve (18), and each indoor expansion valve (18). Adjust from closed to open. Thereby, the needle (76) of each indoor expansion valve (18) is slightly raised. When the refrigerant charging operation is started, the valve control unit (53) performs superheat degree control on each indoor unit (13). Then, after a lapse of a predetermined first time (for example, 30 seconds) from the refrigerant charging operation, the lower limit correction unit (54) of the valve control unit (53) starts the lower limit correction operation.

  Here, when the refrigerant charging operation is performed in a state where the temperature of the indoor air is low, such as in winter, that is, the temperature of the air sent to the indoor heat exchanger (37) is lower than that in the normal operation, Less heat is absorbed by the exchanger (37). For this reason, each indoor expansion valve (18) is controlled so that the flow rate of refrigerant passing through each indoor heat exchanger (37) is reduced by superheat control, so the flow rate standard at the time of full opening is determined in accordance with normal operation. In each indoor expansion valve (18), the control pulse (EV) may remain unchanged with the lower limit command value (EVL). As described above, since some expansion valves are closed when the control pulse (EV) is equal to the lower limit command value (EVL), the refrigerant passes through the indoor expansion valve (18). In some cases, the refrigerant charging operation cannot be continued. This lower limit correction operation is performed to solve such a problem.

  In the lower limit correction operation, first, the lower limit correction section (54), in step 1 (ST1), the control pulses (EV) of the indoor expansion valves (18) of all the indoor units (13) are equal to the lower limit command value (EVL). It is determined whether or not. If the control pulse (EV) of the indoor expansion valves (18) of all the indoor units (13) is equal to the lower limit command value (EVL), the lower limit correction unit (54) performs Step 2 (ST2). On the other hand, if the control pulse (EV) of the indoor expansion valve (18) of any indoor unit (13) is greater than the lower limit command value (EVL), the lower limit correction unit (54) performs the lower limit correction operation. finish.

  In Step 2 (ST2), when the lower limit command value (EVL) has already been corrected in the current refrigerant charging operation, the lower limit correction unit (54) starts from the previous correction of the lower limit command value (EVL). It is determined whether or not the elapsed time has reached a predetermined reference time (for example, 30 seconds). The lower limit correction unit (54) performs step 3 (ST3) when the elapsed time from the previous correction of the lower limit command value (EVL) has reached a predetermined reference time. On the other hand, when the elapsed time from the previous correction of the lower limit command value (EVL) has not reached the predetermined reference time, the lower limit correction unit (54) ends the lower limit correction operation. The lower limit correction unit (54) omits step 2 (ST2) and performs step 3 (ST3) when the lower limit command value (EVL) has not been corrected yet in the current refrigerant charging operation. .

  In step 3 (ST3), the lower limit correction part (54) performs a determination operation for determining whether or not the indoor expansion valve (18) is in a closed state. This determination operation is performed only when the control pulses (EV) of the indoor expansion valves (18) of all the indoor units (13) are equal to the lower limit command value (EVL). In addition, this determination operation is performed when the lower limit command value (EVL) has already been corrected in the current refrigerant charging operation and the elapsed time after the correction of the lower limit command value (EVL) reaches the reference time. It is done after waiting.

  In this determination operation, a predetermined determination condition composed of the first condition and the second condition is used. The first condition is a condition that the state where the measured value of the suction pressure sensor (32) is lower than the first low-pressure reference value (for example, 2 kPa) exceeds a predetermined determination time (for example, 90 seconds). The second condition is a condition that the measured value of the suction pressure sensor (32) falls below a second low pressure reference value (for example, 1 kPa) that is smaller than the first low pressure reference value. The second low pressure reference value is set to a value smaller than the first low pressure reference value. The determination condition is satisfied when at least one of the first condition and the second condition is satisfied. If the determination condition is satisfied, the lower limit correction unit (54) determines that the indoor expansion valves (18) of all the indoor units (13) are closed, and performs Step 4 (ST4). On the other hand, if the determination condition is not satisfied, the lower limit correction unit (54) ends the lower limit correction operation.

  In step 4 (ST4), the lower limit correction unit (54) corrects the lower limit command value (EVL) using Equation 1 shown below. However, the lower limit correction unit (54) does not correct the lower limit command value (EVL) when the corrected lower limit command value (EVL) exceeds a predetermined upper limit value (for example, 200 pulses). The lower limit command value (EVL) is corrected within the range below the upper limit value.

Formula 1: EVL '= EVL + ΔE
In Equation 1, EVL ′ represents a corrected lower limit command value, EVL represents a lower limit command value before correction, and ΔE represents a corrected opening (for example, ΔE = 10 pulses). Further, the upper limit value assumes the maximum value of the variation range due to individual differences in the opening command value when the indoor expansion valve (18) changes from the closed state to the open state.

  When step 4 ends, the lower limit correction unit (54) ends the lower limit correction operation. Then, the lower limit correction unit (54) performs the lower limit correction operation again after a predetermined time (for example, 5 seconds) has elapsed. The lower limit correction unit (54) repeatedly performs the lower limit correction operation until the refrigerant charging operation is completed.

  When the lower limit command value (EVL) is corrected in step 4 (ST4), the valve control unit (53) generates a pulse signal having the corrected lower limit command value (EVL ') as a control pulse (EV). Output to the valve (18) to adjust the opening of each indoor expansion valve (18) to the open side. In each indoor expansion valve (18), the needle (76) rises slightly. When the needle (76) rises to create a gap between the needle (76) and the valve seat (81), the indoor expansion valve (18) is opened. When the indoor expansion valve (18) is opened, the pressure of the low-pressure side refrigerant sucked into the compressor (30) increases, and the measured value of the suction pressure sensor (32) is larger than the first low-pressure reference value. Therefore, in the next lower limit correction operation, the determination condition is not satisfied, and the lower limit command value (EVL) is not corrected.

  On the other hand, if the indoor expansion valve (18) does not open even when the needle (76) rises, the pressure of the low-pressure refrigerant sucked into the compressor (30) does not change. Even in the operation, the determination condition is satisfied, and the lower limit command value (EVL) is corrected again.

-Effect of the embodiment-
In the present embodiment, when it is determined that the indoor expansion valve (18) is in the closed state while the control pulse (EV) is equal to the lower limit command value (EVL) during the refrigerant charging operation, By correcting the value to a large value, the indoor expansion valve (18) is adjusted to the open side. That is, when it is detected that the indoor expansion valve (18) is in a closed state when the control pulse (EV) becomes equal to the lower limit command value (EVL), the indoor expansion valve (18) opens on the open side. Adjusted to. For this reason, the refrigerant is adjusted so that the refrigerant can pass through the indoor expansion valve (18), thereby preventing the refrigerant charging operation from being continued due to the indoor expansion valve (18) being closed. can do.

  In the present embodiment, whether or not the indoor expansion valve (18) is closed is determined using two conditions having different low-pressure reference values. In the first condition out of the two conditions, the duration of the state where the pressure of the low-pressure side refrigerant is lower than the low-pressure reference value is used in the determination. For this reason, since it is possible to determine whether the indoor expansion valve (18) is closed more accurately than when determining whether the indoor expansion valve (18) is closed under only one condition, It can be further reliably prevented that the refrigerant charging operation cannot be continued due to the indoor expansion valve (18) being closed.

  In the present embodiment, the determination operation is performed after waiting for a certain amount of time to elapse after the indoor expansion valve (18) is adjusted to the open side. Here, when the indoor expansion valve (18) changes from the closed state to the open state by correcting the lower limit command value (EVL) to a large value, the pressure of the low-pressure side refrigerant begins to change, but the indoor expansion valve (18) A certain amount of time is required until the pressure of the low-pressure side refrigerant is stabilized after the change to the open state. For this reason, when the determination operation is performed immediately after adjusting the indoor expansion valve (18) to the open side, the pressure of the low-pressure side refrigerant is not stable, so the indoor expansion valve (18) is in the open state. There is a possibility that the lower limit command value (EVL) is corrected to a larger value without noticing. On the other hand, in this embodiment, after the indoor expansion valve (18) is changed to the open state, the determination operation is performed after waiting for the pressure of the low-pressure side refrigerant to stabilize. Therefore, it is not erroneously determined that the indoor expansion valve (18) is closed even though the indoor expansion valve (18) is open, and the lower limit command value (EVL) is accurately set. Can be set to

  In the present embodiment, the lower limit command value (EVL) is corrected within a range equal to or lower than the upper limit value. Here, as described above, the control pulse (EV) when the indoor expansion valve (18) changes from the closed state to the open state varies depending on the indoor expansion valve (18). However, the range of variation of the control pulse (EV) when the indoor expansion valve (18) is opened is determined to some extent. That is, even if the indoor expansion valve (18) has a large amount of variation, the indoor expansion valve (18) is always opened when the lower limit command value (EVL) is increased to some extent. In the present embodiment, in consideration of the above, the lower limit command value (EVL) is corrected within a range equal to or lower than the upper limit value. Accordingly, for example, it is possible to prevent the lower limit command value (EVL) from being corrected to a large value exceeding the upper limit value due to erroneous determination or the like even though the indoor expansion valve (18) is in the open state. .

<< Other Embodiments >>
About the said embodiment, it is good also as following structures.

  About the said embodiment, the number of indoor units (13) may be one. In this case, as shown in FIG. 5, step 1 (ST1) in FIG. 4 of the above embodiment is not performed in the lower limit correction operation.

  Moreover, about the said embodiment, the lower limit correction | amendment part (54) may be comprised so that a final lower limit command value (EVL) at the time of a lower limit correction | amendment operation can be memorize | stored. In this case, the stored lower limit command value (EVL) is used as the initial value in the next refrigerant charging operation.

  In the above embodiment, the refrigeration apparatus (10) may be configured to perform a supercritical cycle in which the high pressure of the refrigeration cycle is set to a value higher than the critical pressure of the refrigerant. In that case, one of the outdoor heat exchanger (34) and the indoor heat exchanger (37) operates as a gas cooler, and the other operates as an evaporator.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for a refrigeration apparatus including a refrigerant circuit provided with an expansion valve having a variable opening.

1 is a schematic configuration diagram of a refrigeration apparatus according to an embodiment of the present invention. It is a longitudinal section of an indoor expansion valve concerning an embodiment of the present invention. It is a chart showing the flow characteristic of the indoor expansion valve concerning the embodiment of the present invention. It is a flowchart showing the flow of the minimum correction | amendment operation | movement in the freezing apparatus which concerns on embodiment of this invention. It is a flowchart showing the flow of the minimum correction | amendment operation | movement in the freezing apparatus which concerns on other embodiment.

Explanation of symbols

10 Refrigeration equipment 17 Indoor circuit (use side circuit)
18 Indoor expansion valve (expansion valve)
DESCRIPTION OF SYMBOLS 20 Refrigerant circuit 30 Compressor 34 Outdoor heat exchanger 36 Outdoor expansion valve 37 Use side heat exchanger (indoor heat exchanger)
50 controller 53 valve control unit (valve control means)
54 Lower limit correction part

Claims (5)

A refrigerant circuit (20) provided with a compressor (30), a use side heat exchanger (37), and an expansion valve (18) having a variable opening for adjusting the refrigerant flow rate of the use side heat exchanger (37). )When,
Valve control means (53) for controlling the opening of the expansion valve (18),
During the refrigerant charging operation in which the refrigerant circuit (20) is charged with the refrigerant while performing the refrigeration cycle so that the use side heat exchanger (37) operates as an evaporator in the refrigerant circuit (20), the valve control means ( 53) sets the opening command value larger than a predetermined lower limit command value so that the superheat degree of the refrigerant at the outlet of the use side heat exchanger (37) becomes a predetermined target superheat degree. 18) a refrigeration apparatus for controlling the opening of the expansion valve (18) by outputting to 18),
The valve control means (53) is arranged between the expansion valve (18) and the suction side of the compressor (30) in a state where the opening command value is equal to the lower limit command value during the refrigerant charging operation. Based on the state of the low-pressure side refrigerant, a determination operation is performed to determine whether or not the expansion valve (18) is in a closed state, and the determination operation determines that the expansion valve (18) is in a closed state. In this case, the lower limit command value is corrected to a large value. In claim 1,
In the refrigerant circuit (20), a plurality of usage side circuits (17) provided with the usage side heat exchanger (37) and the expansion valve (18) are connected in parallel,
The valve control means (53) performs the determination operation only when the opening command values of the expansion valves (18) of all the use side circuits (17) are equal to the lower limit command value during the refrigerant charging operation. The refrigeration apparatus corrects the lower limit command value when it is determined in the determination operation that the expansion valves (18) of all the use side circuits (17) are closed. In claim 1 or 2,
The valve control means (53) includes a first condition in which the duration of the state where the pressure of the low-pressure side refrigerant is below a predetermined first low-pressure reference value reaches a predetermined determination time, and the pressure of the low-pressure side refrigerant is When at least one of the second condition lower than a predetermined second low-pressure reference value smaller than one low-pressure reference value is satisfied, it is determined that the expansion valve (18) is in the closed state by the determination operation. A refrigeration apparatus characterized by. In any one of Claims 1 thru | or 3,
After correcting the lower limit command value in the refrigerant charging operation, the valve control means (53) waits for the elapsed time after the correction of the lower limit command value to reach a predetermined reference time, and then performs the determination operation. A refrigeration apparatus characterized by performing In any one of Claims 1 thru | or 4,
The refrigeration apparatus, wherein the valve control means (53) corrects the lower limit command value within a range not more than a predetermined upper limit value during the refrigerant charging operation.

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