KR20080022547A - A cooling device and the control method - Google Patents

Abstract

The present invention relates to a cooling device (1) and a control method thereof, which prevent the motor of a variable speed compressor (2) performing the refrigerant cycle from unexpected stalls due to reasons of overheating or not being able to respond to the thermodynamic load resulting from heavy work load like high ambient temperature or the frequent opening closing of the door by means of a control method implemented via a control card (5). ® KIPO & WIPO 2008

Description

Cooling device and its control method {A COOLING DEVICE AND THE CONTROL METHOD}

The present invention relates to a cooling device including a compressor that functions efficiently under a large operating load.

In a cooling arrangement, the selection of the compressor in the cooling system takes into account limited operating conditions depending on the climatic zones, and as a result the capacity of the compressor can be more than necessary because the maximum possible operating load is taken into account. More compressor capacity than necessary can increase the number of stop start-ups and increase the loss of cycles. To overcome this condition, the compressor is selected according to the actual operating conditions leading up to a larger part of the life expectancy of the compressor, and the compressor speed, ie the rotational speed (rpm) of the compressor motor, requires that the cooling unit operate within the limit conditions. If it is changed. Various control algorithms have been devised in a cooling system using a variable speed compressor motor that determines when the compressor functions at normal speed and when functioning at higher speed. The compressor speed is accelerated by the assistance of the electronic card when the cooling device is operated under severe operating conditions such as high ambient temperature or frequent opening and closing of the door. In this case, the compressor is supplied via an electronic card instead of network power. Occasionally, the compressor may be overheated or stopped because it cannot react to thermodynamic loads under severe operating conditions resulting in unexpected stalls in the compressor supplied through the electronic card. If the compressor starts to operate after a stop, the cut-out condition is repeated repeatedly due to algorithmic requirements, and frequent shutoffs of the compressor result in reduced efficiency.

In US Pat. No. 6,231,306, the gas turbine engine detects a compressor stall, evaluates the signal received from the sensor, compares the detected signal with a predetermined threshold indicative of a good compressor, and indicates an impending stop condition. Means for providing a signal.

In US Pat. No. 6532433, in a method for monitoring and controlling a compressor, at least one compressor operating variable is monitored to obtain time-series data, the time series data using a Kalman filter. Is filtered. The stall precursor of the compressor under heavy load is detected before the compressor stops as a result of this monitoring method.

In GB 2292847, in a single-phase induction motor used in a compressor, a current detector detects a motor stop under high load, and a relay shuts off the capacitor.

In British Patent GB 1109346, in a refrigerant compressor, the starting device acts to hold the excitation of the auxiliary winding after the motor is started, so as to compensate that the operating torque of the compressor falls below a normal stop torque of the motor. Overcomes the extreme starting torque of the compressor for a long time.

It is an object of the present invention to implement a cooling device and a control method which prevent the unexpected continuous stop of the compressor.

In the cooling device and control method implemented to achieve the object of the present invention, the motor battery card operates the compressor motor under high load and speed during start and stop cycles by the instruction of the thermostat.

As the compressor continues to operate in successive stop and start cycles, it is supplied through the network for a time period at each startup, and the compressor motor functions at a constant speed. Thus, the electronic circuit that controls the motor speed protects against high currents attracted at start-up.

During operation of the compressor, the thermal protection device for detecting the motor temperature may cut off the supply current so that the thermostat stops the compressor due to overheating before giving a stop indication.

If the electronic card detects that the compressor has stopped as the thermal protection device cuts off the current, it is an unexpected stop due to the high load condition.

When the compressor is about to start operation again, the compressor waits after such a stop cycle, because a predetermined waiting time has elapsed before starting so that the pressure imbalance between the compression and suction portions of the compressor is reduced for a period of time. You can start faster.

When the compressor starts operation after waiting for a predetermined time period, it is supplied through a network power source that generates an operation time period at a constant speed longer than the time period when the operation is started by a signal of the thermostat.

If the compressor is operated after an unexpected stop cycle, whether or not the thermal protection device is open should be detected immediately, and thus using a separate thermal sensor to detect the temperature of the thermal protection device is beneficial for transmitting the thermal protection device to the electronic card.

The cooling apparatus and control method realized for achieving the object of the present invention are shown in the accompanying drawings.

1 is a schematic view of a cooling device,

2 is a flow chart of a control method,

3 is a graph of speed-time and temperature-time for compressor operation of a cooling device.

Reference numerals for the elements shown in the drawings are as follows.

1: cooling device 2: compressor

3: thermal protection device 4: thermostat

5: electronic card 6: thermal sensor of thermal protection device

The cooling device 1 comprises a variable speed compressor 2 provided for carrying out a refrigeration cycle; Detecting the temperature of the compressor 2 opens it to a value higher than the preset temperature, cuts off the current I to stop the operation of the compressor 2, and lowers it below the preset temperature to provide a restart of the compressor 2. A thermal protection device 3 which closes to the value; A thermostat 4 which provides cut-in and cut-out instructions to the compressor 2; And an electronic card 5 for executing an algorithm for controlling the operating speed of the compressor 2 and the start-stop duration.

While the compressor performs normal operation in successive start-stop cycles (T-on, T-off) caused by the cut-in and cut-out instructions of the thermostat 4, the high current I is applied to the compressor 2 Since the current I required for the motor will be attracted at every startup, the compressor I is drawn directly from the network power supply for a predetermined time period T1 to protect the electronic card 5, and during the time period T1, 2) operates at a constant speed (Vo). When the time period T1 ends, the compressor 2 passes through the electronic card 5 at a variable speed, ie, at a speed different from the constant speed Vo (e.g., a higher speed V1) to provide the required cooling. Operation is started by supplying (FIG. 3).

As the compressor 2 operates, a current I passes through the thermal protection device 3 reaching the motor of the compressor 2. The thermal protection device 3 is arranged on an electrical contact box on the compressor 2 cell and opens and closes in accordance with the change of the ambient temperature. The thermal protection device 3 opens at a temperature higher than a preset value that cuts off the current I from the network power to the compressor 2 motor, and when the temperature drops below the preset value, the current from the network power is compressed. (2) Close to reach the motor. When the compressor 2 motor is overheated, the thermal protection device 3 is provided to stop the compressor 2 and blocks the current I protecting the electronic card 5.

When the thermal protection device 3 blocks the current I for stopping the compressor 2 without receiving an indication from the thermostat 4 for cutout, the pressure in the refrigerant system can be balanced. And no current I is supplied to the compressor 2 during the preset stop time period T2 so as not to heed the cut-in instructions that may be provided by the thermostat 4 during the time period. At the end of the T2 cycle, the compressor 2 is started with a current I supplied independently from the thermostat 4. After startup, the compressor 2 is operated at a constant speed Vo supplied by the current I from the network power applied during the first startup for a time period T3 longer than the time period T1 and then the current. (I) is supplied through the electronic card 5 and operates at the speed of V1. If a cutout instruction is received from the thermostat 4 while the compressor 2 is operating at a speed of Vo or V1, a T-off period is initiated for this instruction.

The control method of the cooling apparatus 2 which prevents unexpected repeating of the compressor 2 consists of the following steps.

The compressor 2 starts operation 100 with a cut-in indication of the thermostat 4

The compressor 2 is operated at a constant speed Vo at start-up and during the time period T1

After the T1 time period is completed, step 102 in which the current I is supplied via the electronic card 5 and the compressor 2 is operated at speed V1.

The thermal protection device 3 controlling 103 whether the current I is interrupted or not

If the thermal protection device 3 has not cut off the current I, then proceeding to controlling 106 the thermostat 4 as to whether or not a cutout indication has been provided;

If the thermal protection device 3 has cut off the current I, stopping 104 for a time period T2 without supplying the current I to the compressor 2.

The compressor 2 is operated at a constant speed Vo for a time period T3 which is longer than the time period T1 with the current I supplied by the network power.

The thermostat 4 is controlled 106 whether or not it provides a cutout indication

If the thermostat 4 does not provide a cutout instruction, the compressor 2 returns to step 102 where the speed V1 is operated;

If the thermostat 4 has provided a cutout indication, the compressor 2 initiates a stop cycle Toff 107.

In one embodiment of the invention, the cooling device 1 comprises a thermal sensor of a thermal protection device for detecting the temperature of the thermal protection device 3. The thermal sensor 6 of the thermal protection device detects the temperature of the thermal protection device 3 which reaches below the preset value at which the thermal protection device 3 closes, and the thermal protection device 3 then carries a current I )). When the thermal protection device 3 stops the compressor 2 by cutting off the current I, if the temperature falls back to a normal value at the end of the stop period T2, the thermal protection device 3 is connected to the current I. The electronic card 5 activates the compressor 3 immediately after or shortly after the thermal protection device 3 is closed with the data received from the thermal sensor 6 of the thermal protection device.

In the control method of the cooling device 1 implemented by the electronic card 5, the repetition of the stop in the start attempt is prevented after the unexpected stop and the start after the unexpected stop of the compressor 2 are successful.

In the embodiment of the present invention, unexpected stop of the compressor 2 is avoided by implementing a simple control method without having to measure and evaluate various variables of the compressor 2, and efficient performance is achieved, thus high ambient temperature or cooling A certain cooling value in the cooling device 1 is achieved under severe operating loads such as frequently opening and closing the door of the device 1.

Claims (4)

In the cooling device (1), A variable speed compressor 2 provided to perform a refrigeration cycle; A thermal protection device (3) for detecting the temperature of the compressor (2); A thermostat 4 providing cut-in and cut-out instructions to the compressor 2 in T-on and T-off periods; And The thermal protection device 3 blocks the current I that stops the compressor 2 without receiving an indication from the thermostat 4 for cutout while the compressor 2 is operating. The end of the T2 cycle without supplying the current I to the compressor 2 for a preset time period T2 without paying attention to cut-in instructions that may be provided by the thermostat 4 The compressor 2 is started with a current I supplied independently from the thermostat 4 at a constant time period T3 longer than the time period T1 for each start after startup. And an electronic card (5) for operating the compressor (2) at a speed (Vo). The method of claim 1, The thermal sensor 6 of the thermal protection device which detects the temperature of the thermal protection device 3 and starts the compressor 2 immediately after or after the closing of the thermal protection device 3 with the electronic card 5. Cooling apparatus further comprises a). In the method of controlling the cooling device 1 of Claim 1 or 2, The compressor (2) starts operation (100) with a cut-in indication of the thermostat (4); The compressor (2) is operated (101) at a constant speed Vo at start-up and during a time period T1; After the T1 time period is completed, step 102 in which current I is supplied via electronic card 5 and compressor 2 is operated at speed V1; Said thermal protection device (3) controlling (103) whether or not current (I) is interrupted; If the thermal protection device (3) has not cut off the current (I), then proceeding to controlling (106) the thermostat (4) as to whether or not to provide a cutout indication; If the thermal protection device (3) has cut off the current (I), stopping (104) for a time period (T2) without supplying a current (I) to the compressor (2); The compressor (2) is operated (105) at a constant speed (Vo) for a time period (T3) longer than the time period (T1) with a current (I) supplied by a network power source; The thermostat (4) is controlled (106) whether or not to provide a cutout indication; If the thermostat 4 does not provide a cutout instruction, returning to step 102 where the compressor 2 is operated at speed V1; And if the thermostat (4) has provided a cutout instruction, the compressor (2) initiates a stop cycle (Toff). The method of claim 3, The stopping period T2 after the thermal protection device 3 cuts off the current I in step 104 is as long as the time period required to balance the pressure in the cooling system. .

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