JPH0447568Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a device for easily checking the performance of a refrigerator.

[Conventional technology]

The performance of various types of refrigerators such as gas absorption refrigerators and turbine refrigerators deteriorates due to impurities in the internal pipes and a decrease in the amount of refrigerant, and they require regular maintenance and inspection. Performance checks at this time require the use of various measuring instruments.

[Problem that the invention attempts to solve]

However, measuring instruments for performance checking are special and expensive, and it has become difficult to prepare them for each piece of equipment.Therefore, there has been a demand for a means to easily check the performance of refrigerators.

[Means for solving problems]

In order to solve the above-mentioned problem, the present invention is constructed by the following means.

That is, means for determining the difference between the refrigerant temperature and the cooling water temperature in the condenser of the refrigerator, a difference value detection means for detecting that the value of the difference by this means is equal to or higher than a certain value, and a capacity control valve for the refrigerator. An opening detection means for detecting that the opening is greater than a predetermined value, a display means for indicating a decrease in performance when the detection forces of these detection means occur simultaneously, and a display means for detecting a start command to the refrigerator. transient state detection means for detecting the period from when the opening command to the capacity control valve is detected until a predetermined period of time has elapsed as a transient state of the refrigerator; While the transient state is detected by this transient state detection means,
and a blocking means for blocking display by the display means.

[Effect]

Therefore, even if the capacity control valve of the refrigerator is opened at a predetermined value or higher, if the difference between the refrigerant temperature and the cooling water temperature in the condenser is a predetermined value or higher, the transmission in this part will be reduced. As the heat pipe thermal resistance increases and the chiller performance deteriorates, these detection forces occur simultaneously, and it is assumed that this is not a transient state immediately after starting the chiller or immediately after changing the opening of the capacity control valve. , which indicates a decrease in performance.

〔Example〕

Hereinafter, details of the present invention will be explained with reference to figures showing embodiments.

Figure 2 is an instrumentation diagram, in which the incoming water pumped by the pump 1 is supplied via a refrigerator (hereinafter referred to as FRZ) 2, a header 3, and a pipe line 4 to load equipment such as a fan coil unit (hereinafter referred to as FRZ). , LE) 5, the water reaches the header 7 as return water through the pipe 6, is pumped again by the pump 1, and circulates through the above route.
It is designed to cool the LE5, and the FRZ2
The pipe line between the refrigerant liquid and cooling water in the condenser of
Thermometers 11 and 12 are provided for each, so that the refrigerant temperature Tm and the cooling water temperature Tw can be measured individually.

In addition, these measurement outputs and the capacity control valve opening degree d of FRZ2 are given to a monitoring device (hereinafter referred to as SUP) 13, where they are sent to a separate control device.
Together with the start command signal S and the capacity control valve opening command signal D given to the FRZ2, it is used to check the performance of the FRZ2.

The SUP 13 sends and receives data signals to and from the central control unit (not shown in the diagram) via the transmission line 19, and while receiving basic monitoring data, it also transmits monitoring data, etc. There is.

Figure 3 shows an absorption refrigerating machine FRZ, such as a gas absorption type.
It is a diagram showing a thermometer implementation situation when using
Water 4 as a refrigerant accumulated below the condenser 41
2 and insert the thermometer 11 into the condenser 41.
A thermometer 12 is inserted into the outlet 43A of the cooling water pipe 43, which serves as a heat transfer tube, to measure the refrigerant temperature Tm and the cooling water temperature Tw.

Note that the cooling water is supplied to the inlet 43B of the cooling water pipe 43.
from the pump 1, is cooled via the absorber 45 and the condenser 41, and is then sent to the outlet 43A.
It is supplied as waste water from

Further, a steam pipe line 46 is provided adjacent to the condenser 41, and an absorption liquid such as diluted lithium bromide is sprayed from an upper pipe line 47 and heated.
It becomes a concentrated absorption liquid 48 and becomes water 42 by absorbing water.
is sprayed from above the absorber 45 via the pipe 49, the heat exchanger 50, and the pipe 51, and is cooled by its latent heat of vaporization.
Pipe 4 again via pump 52 and heat exchanger 50
7 and circulates along this route.

On the other hand, a cold water pipe 53 is provided adjacent to the absorber 45, and water 42 is sprayed from above through the pipe 54, where the water 42 is evaporated and concentrated and absorbed in the absorber 45. It is absorbed into the liquid 55 and dilutes it, and also cools the cooling water pipe 43.

Figure 4 is a block diagram of the SPU13, which is a processor such as a microprocessor (hereinafter referred to as CPU).
21, fixed memory (hereinafter referred to as ROM) 2
2. A variable memory (hereinafter referred to as RAM) 23 and interfaces (hereinafter referred to as I/F) 24 to 27 are arranged around the periphery, and these are connected by a bus bar.
Based on the input data Di such as each measurement output given via the I/F 24 and the data received via the communication I/F 25, the CPU 21 reads the data from the ROM 22.
It executes the instructions inside to perform check calculations and monitoring decisions.

Note that the CPU 21 stores the necessary data in the RAM 2 for check calculations and monitoring decisions.
At the same time, the command is executed while accessing the display unit (hereinafter referred to as DP) 2 via the I/F 26.
The display data is sent to the RAM 2 to display the monitoring status, and in response to the operation output of the keyboard (hereinafter referred to as KB) 30 via the I/F 27, the display data is sent to the RAM 2.
3, data is set or updated, and these are displayed using the DP 29.

FIG. 5 is a front view showing the operation panel of the SUP 13, in which a multi-digit character display 31 and a plurality of indicator lights 32 corresponding to the monitored parts are provided, and these constitute the DP 29, and the KB
30 is provided, and a character display 31 displays data or numerical values in alphanumeric characters or symbols and numbers, while an indicator light 32 provided corresponding to the nameplate 33 displays alarms, etc. It has become a thing.

Fig. 6 is a diagram showing the performance check status of FRZ2 by SUP13, and shows the refrigerant temperature Tm and cooling water temperature Tw for the capacity control valve opening d of the gas valve, steam valve, vane, fuel valve, etc. of FRZ2. It is normal for the difference △T to be proportional to a certain relationship, and if this is the relationship shown by the dotted line, for example,
When the opening degree d is 50% or more and △T is more than the value shown by the solid line, it can be determined that the heat resistance of the condenser heat transfer tube has increased and the performance of FRZ2 has decreased. In this example, the shaded area is in an abnormal state.

FIG. 7 is a flowchart of the monitoring status by the CPU 21, in which a "transient state?" 101 is determined according to changes in the start command S and the opening command D, and if this is N (NO), "Tm> Tx・Tw＞Ty?”
102, it is determined whether the refrigerant temperature Tm and the cooling water temperature Tw exceed the respective set values Tx and Ty, and based on this, the blockage in the heat transfer is checked, and the "X calculation" is performed based on N of this. After performing 111, FRZ
According to the opening signal d from 2, it is determined by "dV ₁ ?" 112 whether d is equal to or greater than a certain value V ₁ , and when this is Y (YES), △ is determined by "XV ₂ ?" 113.
After determining whether or not X according to T is greater than or equal to the predetermined value _V2 , if it is also Y, the indicator light 32 in FIG. In this state, it is determined whether "a certain period of time has elapsed?" 122, and in accordance with this Y, "indicator light is maintained" 123, and thereby FRZ2
Displays performance degradation.

Note that the calculation in step 111 is performed using the following equation.

[(△T d・K)/M] ・100=X(%)...
(1) ΔT: Tm-Tw K: Correction coefficient M: Predicted normal rating value Also, if step 101 is Y or step 112,
When 113 and 122 are N, "X display setting?" 131 is determined by KB30 in FIG. 5, and if this is Y, "X display" 132 is determined by display 31 in FIG.
as a percentage value and step through “RET”.
Repeat steps 101 onwards.

FIG. 1 is a functional block diagram for carrying out the above-mentioned monitoring, in which the refrigerant temperature Tm and the cooling water temperature Tw are given to the calculator 61, where the temperature difference △T
In addition, the comparator 62 as a difference value detection means
When a value higher than a certain value is detected, FRZ2
The comparator 63 serving as the opening value detecting means detects the opening degree d of the capacity control valve from 2000 to 2000 as being equal to or higher than a predetermined value. A timer 66 is started according to the detection power, and an AND gate 67 serving as a blocking means is kept off until the timer 66 times out.

Therefore, immediately after the FRZ2 is started and the opening degree of the capacity control valve is changed, the AND gate 67 is turned off as a transient state by the timer 66, and at other times, the AND gate 67 is turned on, and the comparators 62 and 63 are turned off. If each of the detected forces occurs simultaneously, a drive signal is sent to the display 68 to indicate that the performance has deteriorated.

Therefore, even with the configuration shown in FIG. 1, the same monitoring operation as in FIG. 6 is performed.

As mentioned above, the performance of FRZ2 can be checked with a simple configuration without using any measuring equipment.
This prevents the FRZ2 from operating with degraded performance and consuming excess energy, and makes maintenance and inspection extremely easy.

However, the configurations in FIGS. 1 to 5 can be arbitrarily selected depending on the situation, and in FIG. 7, the steps can be replaced or replaced with equivalent ones according to the conditions. Alternatively, various modifications are possible, such as omitting unnecessary items.

[Effect of idea]

As is clear from the above explanation, according to the present invention, the performance check of the FRZ is automatically performed with a simple configuration, making it easy to discover performance deterioration, maintenance, and inspection, and has a great effect on performance checks of various cooling equipment. is obtained.

[Brief explanation of drawings]

The figures show an embodiment of the present invention, where Fig. 1 is a functional block diagram, Fig. 2 is a schematic diagram, Fig. 3 is a diagram showing the implementation status of a thermometer, Fig. 4 is a block diagram of SUP,
Figure 5 is a front view showing the SUP operation panel, Figure 6
The figure shows the monitoring situation, and FIG. 7 is a flowchart of the monitoring operation. 2...FRZ (freezer), 4, 6...pipeline, 5...
...LE (load equipment), 11, 12...Thermometer, 13
...SUP (monitoring device), 21 ... CPU (processor), 22 ... ROM (fixed memory), 23 ...
RAM (variable memory), 24-27...I/F (interface), 41...condenser, 42...water (refrigerant), 43...cooling water pipe, 43A...outlet,
43B...Inlet, 48...Absorbing liquid, 61...Subtractor, 62, 63...Comparator, 64, 65...Significant circuit, 67...AND circuit, 68...Display device.

Claims (1)

[Scope of Claim for Utility Model Registration] Means for determining the difference between refrigerant temperature and cooling water temperature in a condenser of a refrigerator; difference value detection means for detecting that the value of the difference by the means is greater than a certain value; opening detection means for detecting that the capacity control valve opening of the refrigerator is equal to or higher than a predetermined value; display means for displaying a decrease in performance when the detection forces of the respective detection means occur simultaneously; The transient period of the chiller is defined as the period from when a start command to the refrigerator is detected until a predetermined period of time has elapsed, and from the time when a change in the opening command to the capacity control valve is detected until a predetermined period of time has elapsed. A refrigerating machine performance check device comprising: a transient state detecting means for detecting the state; and a blocking means for preventing the display means from displaying while the transient state is being detected by the transient state detecting means. .