JP2007071514A - Freezer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To carry out positive cooling of a cooling chamber, and to prevent unnecessary defrosting operation in a freezer carrying out cooling operation and defrosting operation of a cooling chamber having an opening and closing door. <P>SOLUTION: The freezer is provided with a refrigerant circuit for a vapor compression type refrigerating cycle having a freezing unit carrying out the cooling operation and the defrosting operation of a freezing showcase, and a control part 200 carrying out operation control. The freezing showcase is provided with two opening and closing doors being a commodity takeout opening, and a commodity carrying-in door. An opening detection part 300 detecting opening of the opening and closing doors is connected to the control part 200. In the freezing unit, as a general rule, the defrosting operation is carried out every six hours, but if it is judged that an opened time of the opening and closing doors is long by an opened time judging part 201 on the basis of a signal from the opening detection part 300, even when six hours have passed from a prior defrosting operation time and it is a defrosting start time, cooling operation is continued instead of starting the defrosting operation. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

    The present invention relates to a refrigeration apparatus, and particularly relates to a refrigeration apparatus that performs a refrigeration operation and a defrosting operation of a cooling chamber.

    2. Description of the Related Art Conventionally, there is a refrigeration apparatus that performs a cooling operation of a cooling chamber and temporarily stops the cooling operation to perform a defrosting operation in order to remove frost attached by the cooling operation. (For example, patent document 1 and patent document 2).

    Patent Document 1 discloses a heat exchanger that is installed in a store such as a convenience store and cools a refrigerated showcase and a freezer showcase, a heat exchanger for air conditioning in the store, and a heat exchanger that is provided outdoors. Describes a refrigeration apparatus connected to a refrigerant circuit of a vapor compression refrigeration cycle. In such a refrigeration system, if the cooling of the showcase is continued for a long time, frost adheres to the surface of the evaporator to increase the heat transfer resistance and the ventilation resistance of the heat exchanger of the showcase. In addition, the cooling capacity decreases. Therefore, for example, normal refrigeration and freezing are temporarily stopped every predetermined time, and defrosting is started.

Patent Document 2 describes a refrigeration apparatus that periodically performs a defrosting operation at predetermined time intervals in a refrigeration apparatus that cools offshore containers.
JP 2004-35395 A JP 2001-183037 A

    By the way, in the refrigeration apparatus as in Patent Documents 1 and 2, in order to carry in and take out the contents of the cooling chamber, the opening / closing door of the cooling chamber may be opened for a long time or frequently. In such a case, the cooling chamber is not sufficiently cooled, and the temperature of the cooling chamber is not lowered and frost is hardly attached, so that the defrosting operation is temporarily unnecessary. However, in a refrigeration apparatus that periodically performs a defrosting operation, even in such a case, the defrosting operation is started after a predetermined cooling operation time has elapsed since the previous defrosting operation. There was a problem that the room could not be cooled and unnecessary defrosting operation was performed.

    The present invention has been made in view of such points, and in a refrigeration apparatus that performs a defrosting operation every predetermined cooling operation time, a defrosting start time after a predetermined cooling operation time has elapsed since the previous defrosting operation, and However, if the opening time of the cooling chamber door is long, the cooling operation is continued to ensure cooling of the cooling chamber and to prevent unnecessary defrosting operation. Objective.

    A first aspect of the invention is a refrigeration apparatus that performs a cooling operation of the cooling chamber (3a) and performs a defrosting operation every time a predetermined cooling operation time elapses. , 3c) measuring means (201) for measuring the cumulative open time at a predetermined time, and the cumulative measured by the measuring means (201) when the predetermined cooling operation time has elapsed since the previous defrosting operation. When the opening time is equal to or longer than a predetermined reference time, a defrosting limiting means (204) is provided for continuing the cooling operation and limiting the defrosting operation instead of starting the defrosting operation.

    In the first aspect of the invention, if the cumulative opening time of the opening / closing doors (3b, 3c) of the cooling chamber (3a) within a predetermined time is equal to or longer than a predetermined reference time, the cooling of the cooling chamber (3a) is insufficient. Since the temperature of the cooling chamber (3a) is not lowered and frost is not formed, the defrosting limiting means (204) continues the cooling operation instead of starting the defrosting operation, and the cooling chamber (3a) In addition to cooling, unnecessary defrosting operation is prevented.

    In a second aspect based on the first aspect, the cooling chamber (3a) is a showcase (3a) installed in a store.

    In the second aspect of the present invention, by restricting the defrosting operation in the showcase (3a), the product in the showcase (3a) is cooled and unnecessary removal in the showcase (3a) is performed. Prevents frost operation.

    In a third aspect based on the second aspect, the opening / closing doors (3b, 3c) are opening / closing doors (3b) for taking out products facing the sales floor in the store.

    In the third invention, since the opening / closing door (3b) for taking out the product is mainly opened and closed by the customer, it is difficult to predict the opening time. Therefore, the measurement means (201) sets the cumulative opening time. Measure reliably.

    In a fourth aspect based on the second aspect, the opening / closing doors (3b, 3c) are opening / closing doors (3c) for carrying goods in the store facing the backyard outside the sales floor.

    In the fourth aspect of the invention, the opening / closing door (3c) for carrying in merchandise fluctuates in opening time due to merchandise carrying work or the like and it is difficult to predict the opening time. Measure reliably.

    According to a fifth invention, in the first invention, a defrosting start means (205) is provided for starting the defrosting operation after the cooling operation by the defrosting restriction means (204) has continued for a predetermined period.

    In the fifth invention, in the first invention, after the cooling operation by the defrosting limiting means (204) is continued for a predetermined period by the defrosting start means (205), the defrosting operation is started.

    According to the first aspect of the present invention, even within the predetermined time of the open / close doors (3b, 3c) of the cooling chamber (3a) even when the predetermined defrosting operation time has elapsed since the previous defrosting operation. If the cumulative open time of the battery is greater than or equal to the predetermined reference time, the cooling operation is continued instead of starting the defrosting operation, so that the cooling chamber is insufficiently cooled due to the opening of the doors (3b, 3c) (3a) can be cooled, and unnecessary defrosting operation can be prevented from being performed on the cooling chamber (3a) where frost formation is not performed.

    Further, according to the second invention, since the cooling chamber (3a) is the showcase (3a) installed in the store, the products in the showcase (3a) can be reliably cooled. In addition, it is possible to prevent unnecessary defrosting operation from being performed on the showcase (3a) where frosting has not been performed.

    Further, according to the third invention, in the second invention, since the opening / closing door (3b, 3c) is the opening / closing door (3b) for taking out the product, the opening / closing door (3b) for taking out the product is Since the opening time is difficult to predict because it is mainly opened and closed by the customer, the opening time can be reliably measured by the measuring means (201) and appropriate defrosting restriction can be performed.

    According to the fourth aspect of the invention, in the second aspect, the opening / closing door (3b, 3c) is an opening / closing door (3c) for carrying a product facing the back yard of the showcase (3a). Since the opening time of the opening / closing door (3c) for product delivery varies depending on the work content, it is difficult to predict the opening time. Defrosting restriction can be performed.

    According to the fifth aspect, in the first aspect, after the cooling operation by the defrost restriction unit (204) is continued for a predetermined period by the defrost start unit (205), the defrost operation is performed. Therefore, it is possible to prevent the defrosting operation from being performed permanently.

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

<< Embodiment of the Invention >>
As shown in FIG. 1, the refrigeration apparatus (10) of the present invention is a refrigeration apparatus installed in a store such as a convenience store, and performs indoor air conditioning operation and cooling operation of the refrigerated showcase (4a). The cooling operation and the defrosting operation of the refrigeration showcase (3a) are performed. The refrigeration apparatus (10) includes an outdoor unit (1), a booster unit (2), a refrigeration unit (3), a refrigeration unit (4), an air conditioning unit (5), and a control unit (200). I have. The outdoor unit (1) is installed outdoors, and the other units (2, 3, 4, 5) are installed in the store.

    The refrigeration unit (3) includes the refrigeration showcase (3a) and is configured to cool the refrigeration showcase (3a). The refrigeration unit (4) includes the refrigeration showcase (4a). In addition, the refrigerated showcase (4a) is configured to be cooled.

    The refrigerated showcase (3a) is formed in a substantially rectangular parallelepiped shape, and has two open / close doors (3b, 3c) on opposite side surfaces. One of the two open / close doors (3b, 3c) is the product take-out door (3b), which faces the sales floor in the store, and is mainly an open / close door for customers in the store to take out the product. The other of the two open / close doors (3b, 3c) is a product carry-in door (3c) that faces the backyard outside the sales floor, and the store clerk carries the product into the frozen showcase (3a). It is an open / close door for display.

    In the refrigeration apparatus (10), as shown in FIG. 2, the outdoor unit (1) includes an outdoor circuit (40), the air conditioning unit (5) includes an air conditioning circuit (100), and the refrigeration unit (4). The refrigerator internal circuit (110) is provided, the refrigeration unit (3) is provided with a freezer internal circuit (130), and the booster unit (3) is provided with a booster circuit (140). In the refrigeration apparatus (10), the refrigerant circuit (20) of the vapor compression refrigeration cycle is configured by connecting these circuits (40, 100,...) With pipes.

    Specifically, in the refrigerant circuit (20), the freezer internal circuit (130) and the booster circuit (140) are connected in series to form the refrigerating circuit (30), and the freezing circuit (30) and the refrigerator internal circuit (110) are connected in parallel to the outdoor circuit (40). The refrigerator internal circuit (110) and the refrigeration circuit (30) are connected to the outdoor circuit (40) via the first liquid side communication pipe (21) and the first gas side communication pipe (22). One end of the first liquid side connection pipe (21) is connected to the outdoor circuit (40), the other end is branched into two, and one of the branches is connected to the liquid side end of the refrigerator internal circuit (110), The other is connected to the liquid side closing valve (31). One end of the first gas side connecting pipe (22) is connected to the outdoor circuit (40), the other end is branched into two, and one of the branched branches is connected to the gas side end of the refrigerator internal circuit (110), The other is connected to the gas side closing valve (32).

    In the refrigerant circuit (20), the air conditioning circuit (100) is connected to the outdoor circuit (40) via the second liquid side communication pipe (23) and the second gas side communication pipe (24). . One end of the second liquid side connecting pipe (23) is connected to the outdoor circuit (40), and the other end is connected to the liquid side end of the air conditioning circuit (100). One end of the second gas side communication pipe (24) is connected to the outdoor circuit (40), and the other end is connected to the gas side end of the air conditioning circuit (100).

<Outdoor unit>
The outdoor circuit (40) of the outdoor unit (1) includes a variable capacity compressor (41), a fixed capacity compressor (42), an outdoor heat exchanger (43), a receiver (44), and an outdoor expansion. And a valve (45). The outdoor circuit (40) is provided with two four-way switching valves (51, 52), two liquid side closing valves (53, 55), and two gas side closing valves (54, 56). . In this outdoor circuit (40), the first liquid side closing pipe (21) is connected to the first liquid side closing valve (53), and the first gas side connecting pipe (22) is connected to the first gas side closing valve (54). However, the second liquid side closing valve (55) is connected to the second liquid side connecting pipe (23), and the second gas side closing valve (56) is connected to the second gas side connecting pipe (24). .

    One end of a first suction pipe (61) is connected to the suction side of the variable capacity compressor (41). The other end of the first suction pipe (61) is connected to the first gas side closing valve (54). On the other hand, one end of the second suction pipe (62) is connected to the suction side of the fixed capacity compressor (42). The other end of the second suction pipe (62) is connected to the second four-way switching valve (52). One end of the suction connection pipe (63) is connected to the first suction pipe (61), and the other end of the suction connection pipe (63) is connected to the second suction pipe (62). The suction connection pipe (63) is provided with a check valve (CV-1) that allows only the refrigerant to flow from one end to the other end between the suction connections (63).

    A discharge pipe (64) is connected to the variable capacity compressor (41) and the fixed capacity compressor (42). One end of the discharge pipe (64) is connected to the first four-way switching valve (51), and the other end is branched into a first branch pipe (64a) and a second branch pipe (64b). The first branch pipe (64a) is connected to the discharge side of the variable capacity compressor (41), and the second branch pipe (64b) is connected to the discharge side of the fixed capacity compressor (42). The second branch pipe (64b) of the discharge pipe (64) has a check valve (CV-3) that allows only refrigerant flow from the fixed capacity compressor (42) to the first four-way selector valve (51). Is provided. One end of a discharge connection pipe (65) is connected to the discharge pipe (64), and the other end of the discharge connection pipe (65) is connected to the second four-way switching valve (52).

    The outdoor heat exchanger (43) is a cross-fin type fin-and-tube heat exchanger that exchanges heat between the refrigerant and the outdoor air. One end of the outdoor heat exchanger (43) is connected to the first four-way switching valve (51) via the closing valve (57). On the other hand, the other end of the outdoor heat exchanger (43) is connected to the top of the receiver (44) via the first liquid pipe (81). The first liquid pipe (81) is provided with a check valve (CV-4) that allows only the refrigerant to flow from the outdoor heat exchanger (43) to the receiver (44).

    One end of the second liquid pipe (82) is connected to the bottom of the receiver (44) via a closing valve (58), and the other end of the second liquid pipe (82) is connected to the first branch pipe (82a). And the second branch pipe (82b). The first branch pipe (82a) of the second liquid pipe (82) is connected to the first liquid side closing valve (53), and the second branch pipe (82b) is connected to the second liquid side closing valve (55). It is connected. The second branch pipe (82b) of the second liquid pipe (82) has a check valve (CV-5) that allows only the refrigerant to flow from the receiver (44) to the second liquid side shut-off valve (55). Is provided.

    In the second branch pipe (82b) of the second liquid pipe (82), one end of the third liquid pipe (83) is interposed between the check valve (CV-5) and the second liquid side stop valve (55). It is connected. The other end of the third liquid pipe (83) is connected to the top of the receiver (44). The third liquid pipe (83) is provided with a check valve (CV-6) that allows only the refrigerant to flow from one end to the other end.

    One end of a fourth liquid pipe (84) is connected downstream of the closing valve (58) in the second liquid pipe (82), and the other end of the fourth liquid pipe (84) is connected to the first liquid pipe (84). 81) is connected between the outdoor heat exchanger (43) and the check valve (CV-4). The fourth liquid pipe (84) is provided with an outdoor expansion valve (45).

    The first four-way switching valve (51) has a first port to the discharge pipe (64), a second port to the second four-way switching valve (52), and a third port to the outdoor heat exchanger (43 ), The fourth port is connected to the second gas side shut-off valve (56), respectively. The first four-way selector valve (51) is in a first state (state indicated by a solid line in FIG. 1) in which the first port and the third port communicate with each other and the second port and the fourth port communicate with each other. ) And a second state (state indicated by a broken line in FIG. 1) in which the first port and the fourth port communicate with each other and the second port and the third port communicate with each other.

    The second four-way switching valve (52) has a first port to the discharge connection pipe (65), a second port to the second suction pipe (62), and a fourth port to the first four-way switching valve ( 51) is connected to the second port. The second four-way switching valve (52) has a third port sealed. The second four-way selector valve (52) is in a first state (state indicated by a solid line in FIG. 1) in which the first port and the third port communicate with each other and the second port and the fourth port communicate with each other. ) And a second state (state indicated by a broken line in FIG. 1) in which the first port and the fourth port communicate with each other and the second port and the third port communicate with each other.

    The outdoor circuit (40) is also provided with an oil separator (70), an oil return pipe (71), an injection pipe (85), and a communication pipe (87). Furthermore, the outdoor circuit (40) is provided with two oil equalizing pipes (72, 73) and two suction side pipes (66, 67).

    The oil separator (70) is provided in the discharge pipe (64) and separates refrigeration oil from the discharge gas of the compressor (41, 42). One end of an oil return pipe (71) is connected to the oil separator (70), and the other end of the oil return pipe (71) is connected to the first suction pipe (61). The oil return pipe (71) is provided with a solenoid valve (SV-5). When the solenoid valve (SV-5) is opened, the refrigeration oil separated by the oil separator (70) is compressed by variable displacement. Returned to the suction side of the machine (41).

    The first oil equalizing pipe (72) has one end connected to the variable capacity compressor (41), the other end connected to the second suction pipe (62), and includes an electromagnetic valve (SV-1). On the other hand, the second oil equalizing pipe (73) has one end connected to the fixed capacity compressor (42), the other end connected to the first suction pipe (61), and includes an electromagnetic valve (SV-2). By appropriately opening and closing the solenoid valves (SV-1, SV-2), the amount of refrigerating machine oil stored in each compressor (41, 42) is averaged.

    The first suction side pipe (66) has one end connected to the second suction pipe (62) and the other end connected to the first suction pipe (61). The first suction side pipe (66) is provided with a solenoid valve (SV-3) and a check valve (CV-2) in order from one end to the other end of the first suction side pipe (66). ing. This check valve (CV-2) only allows the refrigerant to flow from one end to the other end of the first suction side pipe (66). On the other hand, the second suction side pipe (67) is connected so as to connect both sides of the solenoid valve (SV-3) in the first suction side pipe (66). The second suction side pipe (67) is provided with a solenoid valve (SV-4).

    The injection pipe (85) is for performing so-called liquid injection. One end of the injection pipe (85) is connected to the fourth liquid pipe (84) via the closing valve (59), and the other end is connected to the first suction pipe (61). The injection pipe (85) is provided with a flow rate adjustment valve (86) whose opening degree can be adjusted. One end of a communication pipe (87) is connected between the closing valve (59) and the flow control valve (86) in the injection pipe (85). The other end of the communication pipe (87) is connected between the oil separator (70) and the solenoid valve (SV-5) in the oil return pipe (71). The communication pipe (87) is provided with a check valve (CV-7) that allows only the refrigerant to flow from one end to the other end.

    The outdoor circuit (40) is also provided with various pressure sensors (93, 94, 97), temperature sensors (91, 92, 96), and a pressure switch (95). The outdoor unit (1) is provided with an outdoor air temperature sensor (90) and an outdoor fan (48). Outdoor air is sent to the outdoor heat exchanger (43) by the outdoor fan (48).

<Air conditioning unit>
The air conditioning circuit (100) of the air conditioning unit (5) is provided with an air conditioning expansion valve (102) and an air conditioning heat exchanger (101) in order from the liquid side end to the gas side end. The air-conditioning heat exchanger (101) is a cross-fin type fin-and-tube heat exchanger that exchanges heat between refrigerant and room air. The air conditioning expansion valve (102) is configured to be adjustable in opening.

    The air conditioning unit (5) is provided with a heat exchanger temperature sensor (103), a refrigerant temperature sensor (104), an indoor temperature sensor (106), and an air conditioning fan (105). The indoor air in the store is sent to the air conditioning heat exchanger (101) by the air conditioning fan (105).

<Refrigerated unit>
In the refrigerator circuit (110) of the refrigeration unit (4), a refrigeration expansion valve (112) and a refrigeration heat exchanger (111) are provided in order from the liquid side end to the gas side end. The refrigeration heat exchanger (111) is a cross-fin type fin-and-tube heat exchanger that exchanges heat between the refrigerant and the air in the refrigerated showcase (4a). The refrigeration expansion valve (112) is configured to be adjustable in opening.

    The refrigeration unit (4) includes a heat exchanger temperature sensor (113), a refrigerant temperature sensor (114), a refrigerator temperature sensor (116), and a refrigerator fan (115). Air in the refrigerated showcase (4a) is sent to the refrigerated heat exchanger (111) by the refrigerator fan (115).

<Refrigeration unit>
In the freezer circuit (130) of the refrigeration unit (3), a refrigeration expansion valve (132) and a refrigeration heat exchanger (131) are provided in order from the liquid side end to the gas side end. The refrigeration heat exchanger (131) is a cross-fin type fin-and-tube heat exchanger that exchanges heat between the refrigerant and the air in the refrigeration showcase (3a). The refrigeration expansion valve (132) is configured to be adjustable in opening.

    The refrigeration unit (3) is provided with a heat exchanger temperature sensor (133), a refrigerant temperature sensor (134), a freezer temperature sensor (136), and a freezer fan (135). Air in the refrigeration showcase (3a) is sent to the refrigeration heat exchanger (131) by the fan (135) in the freezer.

<Booster unit>
The booster circuit (140) of the booster unit (2) is provided with a booster compressor (141), a four-way switching valve (142), and a bypass pipe (150).

    One end of the suction pipe (143) is connected to the suction side of the booster compressor (141), and one end of the discharge pipe (144) is connected to the discharge side.

    The other end of the discharge pipe (144) is connected to the first port, and the other end of the suction pipe (143) is connected to the second port of the four-way switching valve (142). The four-way switching valve (142) has a third port connected to the gas side shut-off valve (32) via a pipe, and the fourth port connected to the gas side end of the freezer internal circuit (130) via the pipe. It is connected to the. The four-way switching valve (142) is in a first state (state indicated by a solid line in FIG. 2) in which the first port and the third port communicate with each other and the second port and the fourth port communicate with each other. The first port and the fourth port can communicate with each other, and the second port and the third port can communicate with each other.

    The discharge pipe (144) includes an oil separator (145), a high-pressure switch (148), a discharge-side check valve (in order) from the booster compressor (141) toward the four-way switching valve (142). 149). The discharge side check valve (149) only allows the refrigerant to flow from the booster compressor (141) to the four-way switching valve (142).

    The oil separator (145) is for separating the refrigerating machine oil from the discharge gas of the booster compressor (141). One end of an oil return pipe (146) is connected to the oil separator (145), and the other end of the oil return pipe (146) is connected to the suction pipe (143). The oil return pipe (146) is provided with a capillary tube (147). The refrigerating machine oil separated by the oil separator (145) is sent back to the suction side of the booster compressor (141) through the oil return pipe (146).

    One end of the bypass pipe (150) is connected to a pipe connecting the four-way switching valve (142) and the freezer circuit (130). The other end of the bypass pipe (150) is connected between the oil separator (145) and the discharge-side check valve (149) in the discharge pipe (64). Further, the bypass pipe (150) is provided with a bypass check valve (151) that allows only the refrigerant to flow from one end to the other end. The bypass pipe bypasses the booster compressor (141) and flows the refrigerant only when the booster compressor (141) is stopped.

<Control part>
The control unit (200) includes a microprocessor, a ROM, a RAM, and the like, and performs air conditioning operation (cooling / heating) of the air conditioning unit (5), cooling operation of the refrigeration unit (4), and refrigeration unit ( The switching of the refrigerant flow path of the refrigerant circuit (20) is controlled so that the cooling operation and the defrosting operation of 3) are performed. An open detection unit (300) is connected to the control unit (200) via a wired signal line or wirelessly.

    The opening detection unit (300) detects an open state of the product take-out door (3b) and the product carry-in door (3c) of the refrigerated showcase (3a).

    As shown in FIG. 3, the control unit (200) includes an open time determination unit (201), an operation content determination unit (202), a defrost restriction unit (204), and a defrost start unit (205). ) And a defrosting operation unit (203).

    The opening time determination unit (201) is configured as a measuring unit that measures the cumulative opening time of the two open / close doors (3b, 3c) of the refrigerated showcase (3a) within a predetermined time (for example, 1 minute). At the same time, it is determined whether the opening time of the doors (3b, 3c) is long (large) or short (small) depending on whether or not the accumulated opening time is a predetermined reference time (for example, 30 seconds) or more. . The operation content determination unit (202) is configured to determine whether the release time is large or small from the determination unit (201) at a defrost start time when a predetermined cooling operation time (for example, 6 hours) has elapsed since the previous defrost operation. Is output and an execution signal is output to the defrosting operation unit (203), and if the determination signal is a signal that the open time is large, defrost restriction is performed. The execution signal is output to the unit (204).

    The defrosting operation unit (203) receives the signal from the determination unit (202) and starts the defrosting operation of the refrigeration unit (3). On the other hand, the defrosting restriction unit (204) receives the signal from the determination unit (202) and starts the defrosting operation even at the defrosting start time when a predetermined time has elapsed since the previous defrosting operation. Instead, it is configured as a defrosting limiting unit that continues the cooling operation. The defrost start unit (205) is configured as defrost start means for forcibly starting the defrost operation after the cooling operation by the defrost restriction unit (203) has continued for a predetermined period (for example, 1 hour). ing.

-Driving action-
Next, the operation of the refrigeration apparatus (10) of this embodiment will be described. Here, as an example, the cooling operation of the refrigerated showcase (4a) and the refrigerated showcase (3a) during the indoor cooling operation and the defrosting operation of the refrigerated showcase (3a) will be described.

<Cooling operation>
In the cooling operation of the refrigerated showcase (4a) and the refrigerated showcase (3a) during the indoor cooling operation, as shown in FIG. 4, the first four-way switching valve (51) and the second switching valve of the outdoor circuit (40) The four-way switching valve (52) is set to the first state and the outdoor expansion valve (45) is fully closed, while the air conditioning expansion valve (102), the refrigeration expansion valve (112), and the refrigeration expansion valve (132) The opening is adjusted as appropriate. In the booster circuit (140), the four-way switching valve (142) is set to the first state. In this state, the variable capacity compressor (41), the fixed capacity compressor (42), and the booster compressor (141) are operated.

    The refrigerant discharged from the variable capacity compressor (41) and the fixed capacity compressor (42) is sent from the discharge pipe (64) to the outdoor heat exchanger (43) through the first four-way switching valve (51). . In the outdoor heat exchanger (43), the refrigerant dissipates heat to the outdoor air and condenses. The refrigerant condensed in the outdoor heat exchanger (43) passes through the receiver (44), flows into the second liquid pipe (82), and is distributed to each branch pipe (82a, 82b) of the second liquid pipe (82). Is done.

    The refrigerant flowing into the first branch pipe (82a) of the second liquid pipe (82) flows through the first liquid side connecting pipe (21) and then into the refrigerator internal circuit (110) and the freezer internal circuit (130). Distributed.

    The refrigerant flowing into the refrigerator internal circuit (110) is decompressed when passing through the refrigeration expansion valve (112) and then introduced into the refrigeration heat exchanger (111). In the refrigerated heat exchanger (111), the refrigerant absorbs heat from the air in the refrigerated showcase (4a) and evaporates at a set temperature of, for example, about −5 ° C. In the refrigeration unit (4), the air cooled by the refrigeration heat exchanger (111) is supplied into the refrigerated showcase (4a), and the temperature inside the refrigerated showcase (4a) is maintained at about 5 ° C., for example.

    The refrigerant flowing into the freezer internal circuit (130) is reduced in pressure when passing through the refrigeration expansion valve (132) and then introduced into the refrigeration heat exchanger (131). In the refrigeration heat exchanger (131), the refrigerant absorbs heat from the air in the refrigeration showcase (3a) and evaporates at a set temperature of, for example, about −30 ° C. In the refrigeration unit (3), the air cooled by the refrigeration heat exchanger (131) is supplied into the refrigeration showcase (3a), and the temperature inside the refrigeration showcase (3a) is maintained at, for example, about −20 ° C. .

    The refrigerant evaporated in the refrigeration heat exchanger (131) flows into the booster circuit (140), and is sucked into the booster compressor (141) through the four-way switching valve (142). The refrigerant compressed by the booster compressor (141) flows from the discharge pipe (144) through the four-way switching valve (142) to the first gas side communication pipe (22).

    In the first gas side communication pipe (22), the refrigerant flowing through the refrigerator internal circuit (110) and the refrigerant flowing through the booster circuit (140) merge. Thereafter, these refrigerants are sucked into the variable capacity compressor (41) through the first suction pipe (61). The variable capacity compressor (41) compresses the sucked refrigerant and discharges it to the first branch pipe (64a) of the discharge pipe (64).

    On the other hand, the refrigerant flowing into the second branch pipe (82b) of the second liquid pipe (82) is supplied to the air conditioning circuit (100) through the second liquid side connecting pipe (23). The refrigerant flowing into the air conditioning circuit (100) is reduced in pressure when passing through the air conditioning expansion valve (102) and then introduced into the air conditioning heat exchanger (101). In the air conditioning heat exchanger (101), the refrigerant absorbs heat from the room air and evaporates. In the air conditioning unit (5), the indoor air cooled by the air conditioning heat exchanger (101) is supplied into the store. The refrigerant evaporated in the air-conditioning heat exchanger (101) flows into the outdoor circuit (40) through the second gas side communication pipe (24), and the first four-way switching valve (51) and the second four-way switching valve. (52) in order, and then sucked into the fixed capacity compressor (42) through the second suction pipe (62). The fixed capacity compressor (42) compresses the sucked refrigerant and discharges it to the second branch pipe (64b) of the discharge pipe (64).

<Defrosting operation>
During the defrosting operation of the refrigeration showcase (3a), reverse cycle defrost is performed to reversely flow the refrigerant in the refrigeration heat exchanger (131) of the refrigeration unit (3). Although the refrigerant flow in the refrigeration unit (4), the refrigeration unit (3), and the booster unit (2) is different from the above cooling operation, the refrigerant flow in the outdoor unit (1) and the air conditioning unit (5) is the above cooling operation. Same as inside. Here, differences from the cooling operation will be described.

    During the defrosting operation, as shown in FIG. 5, the four-way switching valve (142) of the booster circuit (140) is set to the second state, and the refrigeration expansion valve (132) is held in the fully open state.

    The refrigerant evaporated in the refrigeration heat exchanger (111) flows through the first gas side communication pipe (22), and a part thereof is taken into the booster circuit (140). The refrigerant taken into the booster circuit (140) flows through the suction pipe (143), and is then sucked into the booster compressor (141) and compressed. After flowing through the discharge pipe (144), the refrigerant flows into the refrigeration heat exchanger (131) of the freezer circuit (130), dissipates heat in the refrigeration heat exchanger, and condenses. The frost adhering to the refrigeration heat exchanger (131) is heated and melted by the heat of condensation of the refrigerant.

    The refrigerant condensed in the refrigeration heat exchanger (131) flows into the first liquid side connection pipe (21) through the fully opened refrigeration expansion valve (132), and is supplied to the refrigerator together with the refrigerant sent out from the outdoor circuit (40). It passes through the refrigeration expansion valve (112) of the internal circuit (110) and is sent back to the refrigeration heat exchanger (111).

    As described above, in the defrosting operation of the refrigeration apparatus (10), the heat absorbed by the refrigerant from the air in the refrigerated showcase (4a) of the refrigeration unit (4) and the refrigerant is given to the refrigerant in the booster compressor (141). Heat is used to defrost the refrigeration heat exchanger (131). In addition, since the refrigeration expansion valve (132) is held in the fully opened state, the refrigerant condensed in the refrigeration heat exchanger (131) is sent back to the refrigeration heat exchanger (111), and is stored in the refrigeration showcase (4a). It is used again for cooling the inside air.

<Operation of control unit>
The control unit (200) is controlled so that the cooling operation and the defrosting operation are performed. In principle, the defrosting operation is performed for about 15 to 30 minutes from the defrosting start time every time a predetermined cooling operation time elapses (for example, every 6 hours) from the previous defrosting operation. When the cumulative opening time of the open / close doors (3b, 3c) of the freezer showcase (3a) for one minute is 30 seconds or longer by the processing of the control unit (200) shown in FIG. Therefore, even if it is the defrosting start time, it is controlled to continue the cooling operation instead of starting the defrosting operation.

    As shown in FIG. 3, the opening detection unit (300) provides two open / close doors (3b, 3c) of the refrigeration showcase (3a) to the determination unit (201) of the opening time of the control unit (200). A signal indicating the open state of is output. The signal is output, for example, continuously while the doors (3b, 3c) are opened, or at the start and end of opening. Thereby, in the said determination part (201), the cumulative opening time of the two opening-and-closing doors (3b, 3c) of the freezing showcase (3a) for 1 minute is measured. Here, the cumulative opening time is the total opening time of each of the product take-out door (3b) and the product carry-in door (3c). For example, if the product take-out door (3b) is opened for 1 second and the product entry door (3c) is opened for 1 second in 1 minute, the cumulative opening time is measured as 2 seconds even if the product is opened at the same time. In one minute, when the product take-out door (3b) is opened twice every second for 1 second and the product carry-in door (3c) is not opened at all, the accumulated opening time is measured as 2 seconds.

    After the cumulative opening time of the two open / close doors (3b, 3c) of the refrigerated showcase (3a) is measured in the determination unit (201), as shown in FIG. If the cumulative opening time of the door (3b) is 30 seconds or more, 1 is assigned to the flag and the opening time is set to be long (step ST12). If it is less than 30 seconds, 0 is assigned to the flag and the door is opened. The time is set to be small (step ST13), and this process is repeated every minute. Then, when the defrosting start time after 6 hours has elapsed since the last defrosting operation, the determination unit (201) outputs a determination signal of the open / close time to the determination unit (202), and thereafter the defrosting operation is performed. Until starting, a large / small determination signal is output to the determination unit (202) for each process (every minute) of the determination unit (201).

    In the defrosting operation control of the control unit (200), as shown in FIG. 7, first, in step ST21, it is determined whether or not 6 hours have passed since the previous defrosting operation. If it is less than 6 hours, the cooling operation is continued in step ST26, and the present process ends.

    If it is determined in step ST21 that 6 hours have elapsed since the previous defrosting operation, in step ST23, the determination unit (201) determines whether the open time is large or small. A signal is output. If the determination signal output to the determination unit (202) is a determination signal that the opening time is short, an execution signal is output from the operation content determination unit (202) to the defrosting operation unit (203), and step ST24. The defrosting operation is started at.

    On the other hand, in step ST23, if a determination signal indicating that the open time is long is output from the determination unit (201) to the determination unit (202), the determination unit (202) executes the defrost restriction unit (204). The signal is output and the process proceeds to step ST25. In step ST25, it is determined whether a predetermined period (for example, 1 hour) has elapsed since 6 hours since the previous defrosting operation, that is, whether 7 hours have elapsed since the previous defrosting operation. If it is determined in step ST25 that it is less than 7 hours from the previous defrosting operation, the process proceeds to step ST26, and the normal cooling operation is continued.

    In step ST25, if it is determined that 7 hours or more have elapsed since the previous defrosting operation, a start signal is output from the defrosting limiting unit (204) to the defrosting start unit (205), In ST24, an execution signal is output from the defrost start unit (205) to the defrost operation unit (203), and the defrost operation is started.

-Effect of the embodiment-
In the refrigeration system (10), even if the defrosting start time set in advance is reached, the accumulated opening time for 1 minute of the two doors (3b, 3c) of the refrigeration showcase (3a) should be 30 seconds or more. For example, it is determined that the opening time of the doors (3b, 3c) is long, and the defrosting restriction unit (204) performs the cooling operation instead of the defrosting operation of the refrigeration unit (3), so the cooling is insufficient. It is possible to reliably cool the slight freezing showcase (3a) and to prevent unnecessary defrosting operation from being performed with almost no frost.

    Further, since the defrosting start section (205) forcibly starts defrosting after 1 hour from the defrosting start time, the open / close doors (3b, 3c) of the refrigeration showcase (3a) are provided. ) Can be prevented from being permanently performed by continuing the open state for a long time, and the defrosting operation can be performed at an appropriate timing.

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

    In the refrigeration apparatus (10) of the above embodiment, the reverse cycle defrost of the refrigeration unit (3) during the cooling operation in the store is shown as an example of the defrosting operation, but the method of the defrosting operation is not limited to this. Also in the refrigeration unit (4), the defrosting operation of the refrigeration unit (4) may be performed similarly to the refrigeration unit (3). In this case, for example, a refrigeration apparatus that performs reverse cycle defrosting for both the refrigeration unit and the refrigeration unit may be used, or an off-cycle defrosting or heater system that prevents the refrigerant in the evaporator from flowing for a certain period of time may be used. The freezing apparatus which performs the defrost operation which performs frost may be sufficient. Further, similar control may be performed in the cooling operation and the defrosting operation during the heating operation.

      In the refrigeration apparatus (10), the defrosting operation is performed every 6 hours in principle, but the interval for performing the defrosting operation (every time a predetermined cooling operation time elapses from the previous defrosting operation). Is not limited to 6 hours. Also, depending on whether the 1 minute cumulative opening time of the open / close door (3b, 3c) of the freezer showcase (3a) is 30 seconds or more, the size of the open / close door (3b, 3c) of the freezer showcase (3a) Although determined, the predetermined time and the cumulative opening time for determining the opening / closing time of the open / close doors (3b, 3c) of the refrigeration showcase (3a) are not particularly limited.

    In the refrigeration apparatus (10), the total opening time of both the open / close doors (3b, 3c) of the freezer showcase (3a) is defined as the cumulative open time within a predetermined time. You may make it perform defrost restriction | limiting only by the accumulation open time of 3b, 3c).

    Also, depending on the load caused by opening the open / close doors (3b, 3c) of the refrigerated showcase (3a), the open time of the open / close doors (3b, 3c) is multiplied by a weighting factor to determine the size of the open time. Also good. For example, in summer, the sales floor may be kept at a predetermined low temperature by the cooling operation of the air conditioning unit (5), while the backyard may be at a high temperature that is about the outside temperature. In this case, the time to open the product take-out door (3b) facing the sales floor is accumulated as measured values, and the product carry-in door (3c) facing the backyard is converted to, for example, twice (1 second open) (If it does, it may be accumulated as 2 seconds). Conversely, in winter, the sales floor is kept at a predetermined high temperature, and the backyard is at a low temperature. Therefore, it may be accumulated by applying a weighting factor on the assumption that the load due to opening of the product take-out door (3b) is large.

    Moreover, although the freezing showcase (3a) of the said refrigeration apparatus (10) is provided with the goods taking-out door (3b) and the goods carrying-in door (3c), you may provide only the opening / closing door which faces the sales floor. Further, the refrigerated showcase (4a) may be provided with an opening / closing door, and the defrosting operation may be restricted by the opening / closing door.

    Further, the opening time determination unit (201) may derive the accumulated opening time from the number of times the opening / closing doors (3b, 3c) of the refrigeration showcase (3a) are opened and closed. For example, if the opening / closing time for one time required for taking out the product is almost determined at the product take-out door (3b), a signal indicating that the product take-out door (3b) is open from the opening detection unit (300) is continuously displayed. May be output instead of a signal indicating that it has been opened or closed.

    In the refrigeration apparatus (10), a normal cooling operation is performed during the defrosting operation. However, a cooling operation that suppresses frost formation may be performed. Specifically, during the defrosting operation of the refrigeration unit (3), frosting is achieved by reducing the amount of air in the showcase that exchanges heat with the refrigerant by reducing the rotational speed of the fan (135) in the freezer. The amount of refrigerant circulating may be reduced to reduce frost formation by reducing the opening of the refrigeration expansion valve (132).

    In addition, the opening time determination unit (201) always measures the cumulative opening time of the opening and closing doors (3b, 3c) of the freezer showcase (3a) for 1 minute, and sets the size of the opening time. However, the measurement and setting may be performed only immediately before the defrost start time or immediately before the defrost start time. Also, based on the cumulative opening time of 1 minute of the open / close doors (3b, 3c) of the refrigeration showcase (3a), which is always derived by the opening time determination unit (201), the time period in which the cumulative opening time becomes longer is set. As a prediction, control may be performed so that the defrosting operation is not performed during a time period in which the cumulative opening time becomes long.

    Further, the refrigeration apparatus (10) of the present embodiment is a refrigeration apparatus (10) installed in a store such as a convenience store, and the cooling chamber is a refrigeration showcase (3a). The configuration of the cooling chamber is not particularly limited. For example, the cooling chamber may be a warehouse, a container, a storage, or the like for performing refrigeration or freezing, and may be any refrigeration apparatus that performs such cooling operation and defrosting operation of the cooling chamber.

    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 that performs a refrigeration operation and a defrosting operation of a cooling chamber.

It is a schematic block diagram of a freezing apparatus. It is a schematic block diagram of the refrigerant circuit of a freezing apparatus. It is a block diagram which shows the defrost control performed by a control part. It is a schematic block diagram of the refrigerant circuit which shows the flow of the refrigerant | coolant during cooling operation. It is a schematic block diagram of the refrigerant circuit which shows the flow of the refrigerant | coolant in a defrost operation. It is a flowchart which shows the magnitude determination process of the opening time of a goods taking-out door and a goods carrying-in door. It is a flowchart which shows the defrost control based on the magnitude determination of the opening time of a goods taking-out door and a goods carrying-in door.

Explanation of symbols

3a Refrigerated showcase (cooling room, showcase)
3b Product door (open / close door, open / close door for product removal)
3c Product door (open / close door, open / close door for product removal)
201 Opening time judgment part (measuring means)
204 Defrost restriction part (Defrost restriction means)
205 Defrost start part (Defrost start means)

Claims (5)

A refrigeration apparatus that performs a cooling operation of the cooling chamber (3a) and performs a defrosting operation every time a predetermined cooling operation time elapses,
Measuring means (201) for measuring the cumulative open time of the open / close doors (3b, 3c) of the cooling chamber (3a) for a predetermined time;
Instead of starting the defrosting operation when the predetermined cooling operation time has elapsed from the previous defrosting operation and the cumulative open time measured by the measuring means (201) is equal to or longer than a predetermined reference time. A refrigeration apparatus comprising defrosting limiting means (204) for continuing the cooling operation and limiting the defrosting operation. In claim 1,
The cooling room (3a) is a showcase (3a) installed in a store. In claim 2,
The open / close door (3b, 3c) is a product take-off open / close door (3b) facing the sales floor in the store. In claim 2,
The open / close door (3b, 3c) is an open / close door (3c) for carrying a product facing a backyard outside a sales floor in the store. In claim 1,
A refrigeration apparatus comprising defrosting start means (205) for starting the defrosting operation after the cooling operation by the defrosting restriction means (204) has continued for a predetermined period.

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