JP2000249408A - Refrigeration unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To minimize a capacity difference during the switching of operation to start the drive of a non-inverter compressor. SOLUTION: In a refrigeration unit equipped with an inverter compressor 1A with a frequency control mechanism 13 attached thereto and a non-inverter compressor 1B, when the operation frequency (f) of the inverter compressor 1A is larger than the preset maximum frequency fmax while reaching a limit frequency fs free from protection control, the drive of the non-inverter compressor 1B is started. This can minimize a capacity difference during the switching of the operation to start the operation of the non-inverter compressor 1B.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to capacity control in a refrigeration system having an inverter compressor and a non-inverter compressor provided with a frequency control mechanism.

[0002]

2. Description of the Related Art As shown in FIG. 1, for example, a first type including an inverter compressor 1A provided with a frequency control mechanism 13 is provided.
A refrigeration apparatus comprising a refrigeration cycle A and a second refrigeration cycle B provided with a non-inverter compressor 1B, wherein the first refrigeration cycle A and the second refrigeration cycle B are operated independently. Is well known in the art.

[0003] The first refrigeration cycle A includes an inverter compressor 1A, a four-way switching valve 2A, a heat source side heat exchanger 3A which functions as a condenser during cooling operation and as an evaporator during heating operation, and a reverse heat exchanger 3A. Capillary tubes 4A and 5A each having a stop valve 6A, 7A acting as a pressure reducing mechanism, and a use side heat exchanger 8 acting as an evaporator during cooling operation and as a condenser during heating operation.
A is connected by a refrigerant pipe.
The refrigeration cycle B of the non-inverter compressor 1
B, a four-way switching valve 2B, a heat source side heat exchanger 3B that acts as a condenser during cooling operation and acts as an evaporator during heating operation, and an electronic expansion that acts as a pressure reducing mechanism provided with check valves 6B and 7B, respectively. The valves 4B and 5B are connected by a refrigerant pipe to a use side heat exchanger 8B which functions as an evaporator during the cooling operation and functions as a condenser during the heating operation. 9A, 9B and 10A, 10
B is a flow divider, 11 and 12 are an outdoor fan and an indoor fan.

[0004]

When operating the refrigeration system configured as described above, first, the inverter compressor 1A
Is started to operate the first refrigeration cycle A, and the frequency f of the power supplied to the inverter compressor 1A is increased by the frequency control mechanism 12 as the load increases. When the frequency f of the inverter compressor 1A reaches the preset maximum frequency fmax, the non-inverter compressor 1B starts driving and the operation of the second refrigeration cycle B starts.

However, when the above-described operation control is performed, when the non-inverter compressor 1B starts driving,
Depending on the indoor temperature conditions, as shown in FIG. 6, there occurs a problem that the capacity changes abruptly. For example, the ability and K ₁ when the inverter compressor 1A is operated at the maximum frequency, the sum of the capacity and the non-inverter compressor 1B ability when the inverter compressor 1A is operated at the lowest frequency K _Assuming that ₂ , when driving the non-inverter compressor 1B starts, K ₁ <K ₂ . Therefore, if the indoor load and the cooling / heating capacity are balanced to some extent at the start of driving of the non-inverter compressor 1B, the capacity becomes excessive, and the non-inverter compressor 1B is stopped and only the inverter compressor 1A operates. The operating state is switched as follows. Then, the capacity becomes insufficient, and the non-inverter compressor 1B starts driving immediately. That is, hunting that repeats ON / OFF of the non-inverter compressor 1B occurs, and the life of the non-inverter compressor 1B is shortened. In addition, the temperature of the air blown into the room changes greatly.

SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and has as its object to reduce a capacity difference at the time of operation switching when driving of a non-inverter compressor is started as small as possible. .

[0007]

According to the first aspect of the present invention, as a means for solving the above problems, a frequency control mechanism 1 is provided.
In the refrigerating apparatus provided with the inverter compressor 1A and the non-inverter compressor 1B, the non-inverter compressor 1B is operated when the operating frequency fmax of the inverter compressor 1A reaches the limit frequency fs at which the protection control is not performed. Operation control means for starting driving of the motor.

With the above configuration, when the inverter compressor 1A is driven, the protection control is not performed even when the frequency f of the inverter compressor 1A becomes equal to or higher than the preset maximum frequency fmax. Frequency control is continued until the frequency increases to the limit frequency fs, and f = f
At time s, the non-inverter compressor 1B starts driving. Then, the capacity at which the inverter compressor 1A is operated at the limit frequency fs and K _3, the sum of the capacity and the non-inverter compressor 1B ability when the inverter compressor 1A is operated at the lowest frequency K ₂
Then, at the start of driving of the non-inverter compressor 1B, K ₃ ≧ K ₂ . Therefore, the non-inverter compressor 1
B at the time of the operation switching at which the operation of B starts, the non-inverter compressor 1B
Can be greatly reduced. Further, since the step in capacity at the time of operation switching is minimized, the change in the blown air temperature at the time of operation switching can also be minimized.

As in the invention of claim 2, claim 1
In the refrigeration apparatus described above, the first refrigeration cycle A including the inverter compressor 1A and the second refrigeration cycle B including the non-inverter compressor 1B may be configured to operate independently. is there.

[0010] As in the invention of claim 3, claim 1
In the refrigeration apparatus described above, one refrigeration cycle C may be configured by the inverter compressor 1A and the non-inverter compressor 1B.

[0011] As in the invention of claim 4, claim 1
4. The refrigeration apparatus according to claim 3, further comprising a high-pressure pressure detecting means 14 for detecting a high-pressure pressure PH in a refrigeration cycle including the inverter compressor 1A, and detecting the high-pressure pressure PH by the high-pressure pressure detecting means 14. When the high-pressure pressure PH reaches a set pressure PHs lower than the pressure at which the high-pressure switch 16 operates, the operation control means is operated.
When there is no more room for the high pressure PH in the refrigeration cycle including the inverter compressor 1A due to the increase in the frequency f of A, the non-inverter compressor 1B starts to be driven, and the operation of the high pressure switch 16 for protection control is started. Can be prevented beforehand.

As in the invention of claim 5, claim 1 is
The refrigeration apparatus according to any one of claims 4 to 4, further comprising a low pressure detection means 15 for detecting a low pressure PL in a refrigeration cycle including the inverter compressor 1A, wherein the low pressure detection means 15 detects the low pressure PL. When the operation control means is operated when the low pressure PL reaches a set pressure PLs higher than the pressure at which the low pressure switch 17 operates, the inverter compressor 1
When the low pressure PL in the refrigeration cycle including the inverter compressor 1A is no longer available due to the increase in the frequency f of A, the non-inverter compressor 1B starts to be driven, and the operation of the low pressure switch, which is the protection control, is started. It can be prevented beforehand.

As in the invention of claim 6, claim 1
The refrigeration apparatus according to any one of claims 1 to 5, wherein an operation current I supplied to the inverter compressor 1A.
At the time when the operating current I detected by the current detecting means 18 reaches the set current Is lower than the current at which the overcurrent switch 19 operates, the operating control means is operated. In this case, when the operating current I runs short due to the increase in the frequency f of the inverter compressor 1A, the non-inverter compressor 1B starts to be driven, and the operation of the overcurrent switch 19, which is the protection control, is performed beforehand. Can be prevented.

As in the invention of claim 7, claim 1
7. The refrigeration apparatus according to claim 6, wherein the operation of the inverter compressor 1A is controlled to a capacity larger than the capacity of the non-inverter compressor 1B. It is possible to more reliably prevent the occurrence of a performance step at the start of driving.

As in the invention of claim 8, claim 7
In the refrigeration apparatus, the inverter compressor 1A
Is controlled to a capacity larger than the sum of the capacity of the non-inverter compressor 1B and the minimum operating capacity of the inverter compressor 1A,
It is possible to more reliably prevent the occurrence of a performance step at the start of driving B.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Some preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings.

First Embodiment FIG. 1 shows a refrigerant circuit of a refrigerating apparatus according to a first embodiment of the present invention.

As shown in FIG. 1, this refrigeration system includes a first refrigeration cycle A having an inverter compressor 1A whose capacity is controlled by a frequency control mechanism 13, and a non-inverter compressor 1B having a constant speed operation control. And the second refrigeration cycle A and the second refrigeration cycle B are configured to operate independently. The non-inverter compressor 1B is a compressor for which frequency control is not performed, and includes a compressor whose capacity is controlled. Here, the operation of the inverter compressor 1A is controlled to a capacity larger than the capacity of the non-inverter compressor 1B, and is smaller than the sum of the capacity of the non-inverter compressor 1B and the minimum operation capacity of the inverter compressor 1A. The operation is controlled to a large capacity.

The first refrigeration cycle A includes an inverter compressor 1A, a four-way switching valve 2A, a heat source side heat exchanger 3A that functions as a condenser during cooling operation and an evaporator during heating operation, Capillary tubes 4A and 5A each having a stop valve 6A, 7A acting as a pressure reducing mechanism, and a use side heat exchanger 8 acting as an evaporator during cooling operation and as a condenser during heating operation.
A is connected by a refrigerant pipe.
The refrigeration cycle B of the non-inverter compressor 1
B, a four-way switching valve 2B, a heat source side heat exchanger 3B that acts as a condenser during cooling operation and acts as an evaporator during heating operation, and an electronic expansion that acts as a pressure reducing mechanism provided with check valves 6B and 7B, respectively. The valves 4B and 5B are connected by a refrigerant pipe to a use side heat exchanger 8B which functions as an evaporator during the cooling operation and functions as a condenser during the heating operation. 9A, 9B and 10A, 10
B is a current divider.

The inverter compressor 1A, the non-inverter compressor 1B, the four-way switching valves 2A and 2B, the heat source side heat exchanger 3
A, 3B, electronic expansion valve 4B, capillary tube 4A,
While the check valves 6A and 6B and the flow dividers 9A and 9B are provided in the outdoor unit X, the capillary tubes 5A and
Electronic expansion valve 5B, check valves 7A and 7B, use side heat exchanger 8
A, 8B and flow dividers 10A, 10B are indoor units Y
It is arranged in. Reference numerals 11 and 12 indicate an outdoor fan and an indoor fan.

The first and second refrigeration cycles A and B
The refrigerant is reversibly circulated by the switching operation of the four-way switching valves 2A and 2B, and can be cooled and heated.

The discharge pipe and the suction pipe of the inverter compressor 1A have a high pressure detecting means 14 and a low pressure detecting means 15, and operate at the time of abnormally rising high pressure and abnormal falling of low pressure to protect the compressor. A high pressure switch 16 and a low pressure switch 17 for controlling are provided. Further, the frequency control mechanism 13 includes a current detecting means 18 for detecting an operation current. Further, the inverter compressor 1A is provided with an overcurrent switch 19 that operates when the operating current is abnormally increased to perform protection control.

As shown in FIG. 2, information signals from the frequency control mechanism 13, high pressure detection means 14, low pressure detection means 15 and current detection means 18 (ie, frequency f, high pressure PH, low pressure pressure) PL and current I)
Is to be input to the controller 20,
The controller 20 performs various arithmetic processing based on these information signals, and controls the operation of the inverter compressor 1A and the non-inverter compressor 1B based on the control signals obtained as a result. That is, the controller 20 determines whether the frequency f of the inverter compressor 1A reaches the limit frequency fs at which the protection control is not performed or the high pressure P
H reaches the set pressure PHs lower than the pressure at which the high pressure switch 16 operates, the low pressure PL reaches the set pressure PLs higher than the pressure at which the low pressure switch 17 operates, or the operating current I activates the overcurrent switch 19. Thus, it has a function as an operation control means for starting driving the non-inverter compressor 1B when the set current Is lower than the set current Is is reached.

Next, the operation control of the compressor in the refrigeration system having the above configuration will be described in detail with reference to the flowchart shown in FIG.

In step S1, the inverter compressor 1
When A is started to drive, in step S2, various data (that is, the operating frequency f, the high pressure PH, and the low pressure PL
And the operating current I) are input to the controller 20.

In step S3, the inverter compressor 1
The operating frequency f of A and the preset maximum frequency fmax
Is performed, and while it is determined that f <fmax, the process proceeds to step S10 to perform the normal frequency control. However, if it is determined that f ≧ fmax, the process proceeds to step S4, where the high pressure PH and the set pressure are compared. A comparison with PHs is made. Here, the set pressure PHs is determined by the high pressure switch 16.
Is set to a pressure slightly lower than the pressure at which

If it is determined in step S4 that PH ≦ PHs, the process proceeds to step S5, but PH> PH
If it is determined to be s (that is, if it is determined that the high pressure PH does not have a margin), the process proceeds to step S9, and the non-inverter compressor 1B starts driving.

In step S5, a comparison is made between the low pressure PL and the set pressure PLs. Here, the set pressure PLs is set to a pressure slightly higher than the pressure at which the low pressure switch 17 operates.

If it is determined in step S5 that PL ≧ PLs, the process proceeds to step S6, where PL <PL
If determined to be s (that is, if it is determined that there is not enough margin in the low pressure PL), the process proceeds to step S9, and the non-inverter compressor 1B starts driving.

In step S6, the operation current I is compared with the set current Is. Here, the set current Is
Is set to a current slightly lower than the operating current at which the overcurrent switch 19 operates.

If it is determined in step S6 that I ≦ Is, the process proceeds to step S7, but if it is determined that I> Is (that is, if it is determined that the operating current I does not have a sufficient margin), Proceeding to step S9, the non-inverter compressor 1B starts driving.

In step S7, control is performed to increase the operating frequency f of the inverter compressor 1A. The control is performed until it is determined in step S8 that the operating frequency is equal to the limit frequency fs. In step S8, it is determined that f = fs. Then, in step S9, the non-inverter compressor 1B
Is driven.

As described above, in the present embodiment, when the first refrigeration cycle A is operated by driving the inverter compressor 1A, the frequency f of the inverter compressor 1A is set to the preset maximum frequency fmax. Even in the case described above, the frequency control is continued until the frequency increases to the limit frequency fs at which the protection control is not performed. When f = fs, the non-inverter compressor 1B starts driving,
The operation of the second refrigeration cycle B is started.
Then, the capacity when the inverter compressor 1A is operated at the limit frequency fs is defined as K ₃ , and the inverter compressor 1A
When the sum of the capacity and the non-inverter compressor 1B ability when A is operating at the lowest frequency and K _2, at the time of start of driving the non-inverter compressor 1B, a K ₃ ≧ K _2. Therefore, the capacity step at the time of operation switching when the operation of the non-inverter compressor 1B is started is minimized, and the number of ON / OFF operations of the non-inverter compressor 1B can be greatly reduced. Further, since the step in capacity at the time of operation switching is minimized, the change in the blown air temperature at the time of operation switching can also be minimized.

The high pressure PH reaches the set pressure PHs lower than the pressure at which the high pressure switch 16 operates, the low pressure PL reaches the set pressure PLs higher than the pressure at which the low pressure switch 17 operates, or the operating current I Is the set current Is lower than the current at which the overcurrent switch 19 operates.
, The non-inverter compressor 1 </ b> B is to be started to drive, so that it is necessary to prevent the operation of the high-pressure switch 16, the low-pressure switch 17, and the overcurrent switch 19 which are protection controls. Can be.

In the above description, the second refrigeration cycle is provided with one non-inverter compressor, but the second refrigeration cycle is provided with two or more non-inverter compressors. It can also be. In that case, when the operating frequency of the inverter compressor reaches the limit frequency, the non-inverter compressor starts to be driven sequentially.

Second Embodiment FIG. 5 shows a refrigerant circuit of a refrigeration apparatus according to a second embodiment of the present invention.

In this case, the refrigerating apparatus includes an inverter compressor 1A and a non-inverter compressor 1B connected in parallel, a heat source side heat exchanger 3, an electronic expansion valve 4, and a use side heat exchanger 8
Is provided with one refrigeration cycle C configured together. In the present embodiment, a circuit dedicated to cooling is used, but a circuit that can be used for both cooling and heating may be used. Also in this case, a plurality of non-inverter compressors 1B may be used. The other configuration and operation and effect are the same as those in the first embodiment, and thus the description is omitted.

[0038]

According to the first aspect of the present invention, a refrigeration system including an inverter compressor 1A provided with a frequency control mechanism 13 and a non-inverter compressor 1B (for example, a first refrigeration system including the inverter compressor 1A). A refrigeration system configured to independently operate the cycle A and the second refrigeration cycle B including the non-inverter compressor 1B, or one refrigeration cycle C by the inverter compressor 1A and the non-inverter compressor 1B. Refrigeration apparatus)
When the operation frequency fmax of the inverter compressor 1A reaches the limit frequency fs at which the protection control is not performed, the operation control means for starting the operation of the non-inverter compressor 1B is provided, and the inverter compressor 1A is driven. Even when the frequency f of the inverter compressor 1A becomes equal to or higher than the preset maximum frequency fmax, the frequency control is continued until it rises to the limit frequency fs at which the protection control is not performed. Inverter compressor 1
Since the driving of B is started, the capacity when the inverter compressor 1A is operated at the limit frequency fs is represented by K
₃ and then, when the sum of the capacity and the non-inverter compressor 1B ability when the inverter compressor 1A is operated at the lowest frequency and K _2, at the time of start of driving the non-inverter compressor 1B is, K ₃ ≧ K _2, and the ability level difference in operation when switching the operation of the non-inverter compressor 1B is started can be minimized. Therefore, the number of ON / OFF operations of the non-inverter compressor 1B can be greatly reduced, and the change in the blown air temperature during operation switching can be minimized.

As in the invention of claim 4, claim 1
4. The refrigeration apparatus according to claim 3, further comprising a high-pressure pressure detecting means 14 for detecting a high-pressure pressure PH in a refrigeration cycle including the inverter compressor 1A, and detecting the high-pressure pressure PH by the high-pressure pressure detecting means 14. When the high-pressure pressure PH reaches a set pressure PHs lower than the pressure at which the high-pressure switch 16 operates, the operation control means is operated.
When there is no more room for the high pressure PH in the refrigeration cycle including the inverter compressor 1A due to the increase in the frequency f of A, the non-inverter compressor 1B starts to be driven, and the operation of the high pressure switch 16 for protection control is started. Can be prevented beforehand.

As in the invention of claim 5, claim 1
5. The refrigeration apparatus according to claim 4, further comprising a low pressure detection means 15 for detecting a low pressure PL in a refrigeration cycle including the inverter compressor 1A, wherein the low pressure detection means 15 detects the low pressure PL. When the operation control means is operated when the low pressure PL reaches a set pressure PLs higher than the pressure at which the low pressure switch 17 operates, the inverter compressor 1
When the low pressure PL in the refrigeration cycle including the inverter compressor 1A is no longer available due to the increase in the frequency f of A, the non-inverter compressor 1B starts to be driven, and the operation of the low pressure switch which is the protection control is started. It can be prevented beforehand.

As in the invention of claim 6, claim 1
The refrigeration apparatus according to any one of claims 1 to 5, wherein an operation current I supplied to the inverter compressor 1A.
At the time when the operating current I detected by the current detecting means 18 reaches the set current Is lower than the current at which the overcurrent switch 19 operates, the operating control means is operated. In this case, when the operating current I runs short due to the increase in the frequency f of the inverter compressor 1A, the non-inverter compressor 1B starts to be driven, and the operation of the overcurrent switch 19, which is the protection control, is performed beforehand. Can be prevented.

As in the invention of claim 7, claim 1
7. The refrigeration apparatus according to claim 6, wherein the operation of the inverter compressor 1A is controlled to a capacity larger than the capacity of the non-inverter compressor 1B. It is possible to more reliably prevent the occurrence of a performance step at the start of driving.

As in the invention of claim 8, claim 7
In the refrigeration apparatus, the inverter compressor 1A
Is controlled to a capacity larger than the sum of the capacity of the non-inverter compressor 1B and the minimum operating capacity of the inverter compressor 1A,
It is possible to more reliably prevent the occurrence of a performance step at the start of driving B.

[Brief description of the drawings]

FIG. 1 is a refrigerant circuit diagram of a refrigeration apparatus according to a first embodiment of the present invention.

FIG. 2 is a block diagram showing an operation control system in the refrigeration apparatus according to the first embodiment of the present invention.

FIG. 3 is a flowchart showing the contents of operation control in the refrigeration apparatus according to the first embodiment of the present invention.

FIG. 4 is a characteristic diagram showing a relationship among an operation frequency and a capacity, a high pressure, a low pressure, and an operation current during operation control in the refrigeration apparatus according to the first embodiment of the present invention.

FIG. 5 is a refrigerant circuit diagram of a refrigeration apparatus according to a second embodiment of the present invention.

FIG. 6 is a characteristic diagram illustrating a relationship between an operation frequency and a capacity at the time of operation control in a conventional refrigeration apparatus.

[Explanation of symbols]

1A is an inverter compressor, 1B is a non-inverter compressor,
13 is a frequency control mechanism, 14 is a high pressure detection means, 15
Is a low pressure detection means, 16 is a high pressure switch, 17 is a low pressure switch, 18 is a current detection means, 19 is an overcurrent switch, 20 is a controller, A is a first refrigeration cycle, B is a second refrigeration cycle, f is the operating frequency, fma
x is the maximum frequency, fs is the set frequency, PH is the high pressure,
PHs is the set pressure, PL is the low pressure, PLs is the set pressure, I is the operating current, and Is is the set current.

Continued on the front page (72) Inventor Shinichi Watanabe 1304 Kanaoka-cho, Sakai City, Osaka Prefecture Daikin Industries, Ltd.Kanaoka Plant, Sakai Works Co., Ltd. Inside the factory (72) Inventor Hiroyuki Kawakita 1304 Kanaokacho, Sakai-shi, Osaka Daikin Industries, Ltd. Sakai Seisakusho Kanaoka factory F-term (reference) 3L060 AA01 CC10 CC16 CC19 DD01 DD02 DD03 EE02 EE04

Claims (8)

[Claims] 1. A refrigeration system comprising an inverter compressor (1A) provided with a frequency control mechanism (13) and a non-inverter compressor (1B), wherein the inverter compressor (1
A refrigerating apparatus, further comprising operation control means for starting driving the non-inverter compressor (1B) when the operation frequency (fmax) of (A) reaches a limit frequency (fs) at which protection control is not performed. 2. A first refrigeration cycle (A) including the inverter compressor (1A) and a second refrigeration cycle (B) including the non-inverter compressor (1B) are independently operated. 2. The refrigeration apparatus according to claim 1, wherein the refrigeration apparatus is configured to perform the following. 3. The refrigeration apparatus according to claim 1, wherein one refrigeration cycle (C) is constituted by the inverter compressor (1A) and the non-inverter compressor (1B). 4. A high pressure detecting means (14) for detecting a high pressure (PH) in a refrigeration cycle including the inverter compressor (1A), and a high pressure detected by the high pressure detecting means (14). The said operation control means is operated when the pressure (PH) reaches a set pressure (PHs) lower than the pressure at which the high pressure switch (16) operates. The refrigeration apparatus according to any one of the preceding claims. 5. A low pressure detection means (15) for detecting a low pressure (PL) in a refrigeration cycle including the inverter compressor (1A), and a low pressure detected by the low pressure detection means (15). The operation control means is operated when the pressure (PL) reaches a set pressure (PLs) higher than the pressure at which the low pressure switch (17) operates. The refrigeration apparatus according to any one of the preceding claims. 6. A current detecting means (18) for detecting an operating current (I) supplied to the inverter compressor (1A), and an operating current (I) detected by the current detecting means (18). 6. The apparatus according to claim 1, wherein the operation control means is operated when the current reaches a set current (Is) lower than the current at which the overcurrent switch (19) operates. A refrigeration apparatus according to claim 1. 7. The method according to claim 1, wherein the operation of the inverter compressor (1A) is controlled to a capacity larger than the capacity of the non-inverter compressor (1B). A refrigeration apparatus according to any one of the preceding claims. 8. The operation control of the inverter compressor (1A) to a capacity larger than the sum of the capacity of the non-inverter compressor (1B) and the minimum operation capacity of the inverter compressor (1A). The refrigerating apparatus according to claim 7, wherein the refrigerating apparatus is used.