JPS62190352A - Method of controlling plurality of heat source apparatuses - Google Patents

Abstract

PURPOSE:To improve the heat efficiency of all the heat source apparatuses by increasing a load carried by first heat supply apparatus when a parallel operation is carried out by use of a first heat supply apparatus and a second heat source apparatus having a heat efficiency lower than that of the first heat supply apparatus. CONSTITUTION:When it is judged that temperature detected by a temperature detection element 10 does not reach a value set at a temperature setting circuit 14, another second heat source apparatus 6 is started, and the operation is started. Thus, when the charged load of the second heat source apparatus 6 is less than an allowable load, it is possible to supply a fluid having a temperature set in a temperature setting circuit 15 can be supplied. In this case, by setting a temperature set in a temperature setting circuit 13 to a temperature higher than a temperature desired in a load 4, a value at which the first heat source apparatus 1 can perform a full-load operation, is determined. Thus, the first heat source apparatus 1 performs a substantially full-load operation, and hence the full heat efficiency can be improved when the second heat source apparatuses 5 and 6 are in operation.

Description

DETAILED DESCRIPTION OF THE INVENTION Technical Field The present invention provides a first heat source device such as a heat pump having a pressure of 18 years with good thermal efficiency, and a second heat source device having low thermal efficiency such as a boiler. Provides multiple heat rJ
, relates to a method of controlling photography.

BACKGROUND TECHNOLOGY In order to perform space heating, hot water supply, hot water pool water supply, etc., heat pumps with high thermal efficiency, which is superior to compressed mass, are used, and boilers with low thermal efficiency but low equipment cost are also used. 71 JrAt has been realized in the past.

Problems to be Solved by the Invention In such prior art, the heat pump and the boiler are operated in parallel (when they are operated in parallel, the load is shared equally.The heat pump has high thermal efficiency, so It is desirable to share the heavy load.

The purpose of the present invention is to use a compressor or to operate in parallel a first heat rAjflA such as a heat bomb 7° and a second heat source device such as a boiler having a lower ν1 thermal efficiency than that, The purpose is to provide a method of controlling multiple heat source devices that improves the overall thermal efficiency as much as possible.

Means for Solving the Problems The present invention includes a first heat source device and a second heat source shrimp whose thermal efficiency is lower than that of the first heat source device, and the first heat source device has The second heat source Fuyo detects the outlet temperature of the fluid from the second heat source IP2 and operates so that the outlet temperature becomes a predetermined first set value. The fluid from the first and second heat source machines is applied to the load, the first heat source machine is operated, and the first heat source machine is operated. The outlet temperature of the heat source machine is ml
A method for controlling a plurality of heat source machines, characterized in that when the set value is not far from the set value, the first set value is changed and the second heat source is activated so that the load shared by the first heat source shrimp is increased. be.

Effect According to the present invention, the first and second heat f2 is configured to detect the outlet temperature of the fluid from their respective heat source devices, and to set the outlet temperature to the predetermined first and second set values. To,
The vehicle is configured to perform the respective operations. First of all
When the heat source machine is operated, the outlet temperature of these 11 heat source machines is
When the first set value is not reached, that is, when the actual load exceeds the permitted load of the first heat source device, the second heat fTA
Start up Iso and perform parallel operation. During this parallel operation,
The first set value is changed so that the load shared by the first heat source device increases.6 For example, when performing heating or hot water supply, the first set value is set to a high value during parallel operation. The load sharing by the first heat source device becomes unreasonable. On the contrary, when performing cooling by parallel operation, the first
The set value is set to a small value to increase the load sharing by the first heat source shrimp.

In this way, it is possible to improve the overall thermal efficiency when the first and second heat sources are operated in parallel.

Embodiment FIG. 1 is an overall block diagram of an embodiment of the present invention. Fluid such as water heated by the first heat source 1 including a heat pump using a compressor is supplied from a pipe 2 to a pipe 3 to a load 4 for space heating, hot water supply, and the like.

A second heat source device 5 having lower thermal efficiency than the first heat source device 1
, 6 are boilers, for example, and the hot water from those second heat source devices 5, 6 passes through the pipes 7, 8 and the pipe 3,
It is supplied to the load 4 mentioned above. Pipe line 2 has a first heat source
A temperature detection element 9 is provided for detecting the exit A degree of the fluid. Similarly, from the second heat source device 5.6 to the pipe line 7
, 8 is determined by the temperature detection rope 10.
．． 11.

A processing circuit 12 realized by a Micro Fumbuuk or the like responds to the outputs of the temperature detection probe 9 and the temperature setting circuit 13, and the temperature detected by the temperature detection probe 9 is set in the temperature setting circuit 13. The ml heat source unit 1 is operated so as to reach the first set value. Such temperature control of the first heat source device 1 is achieved, for example, by controlling the rotational speed of a prime mover such as an internal combustion engine that drives a compressor.

Temperature detection element 10°1 related to second heat rj, Iso 5.6
1 and outputs from temperature setting circuits 14 and 15 provided individually corresponding to these second heat source devices 5 and 6 are given to a processing circuit 12 and detected by temperature detection elements 10 and 11. The processing circuit 12 operates the second heat source device 5.6 so that the temperature reached becomes the second set value set in the temperature setting circuit 14.15. This temperature control is achieved, for example, by changing the combustion characteristics of the burners provided in the second heat source elements 5 and 6.

The operation will be explained with reference to FIG. Moving from step n1 to step n2, first, the ml heat source device 1 is started and brought into operation. 1st heat 'f2. A desired temperature T1 of the fluid used in the load 4 is set in the temperature setting circuit 13 corresponding to P1. By this, load 4
1 is below the allowable load L1 of the first heat generator 1 shown in FIG.
2, the flow from pipe 2 to load 4 via pipe 3 is -
The temperature of the fluid to be returned is determined by the temperature setting circuit 13.
The temperature and T1 are set. In step n3, the temperature detected by the temperature detection λ, S] reaches the temperature setting circuit 13 and reaches the set temperature T1, but 1'! i IL4i, and if so, the first heat source unit continues operation.

The load 4 becomes large and the first heat source (Fll negative load 1
At time L1 when the value exceeds 1, the temperature detected by the temperature detection element 9 does not rise to the temperature T1 set in the temperature setting circuit 3. At this time, step 1
13 to step o4, the temperature setting value in the temperature setting circuit 13 is set to a temperature T 1 a (however, TI<Tin) higher than the desired temperature T1 in the load 4, and the operation of the first heat source device 1 is started. Continue to continue.

In step 115, the -power second heat source device 5 is activated. Temperature setting circuit 1 corresponding to this one second heat source sleep 5
4, the desired temperature T] of the fluid used in load 4 is set. by this,! 52 When the load shared by the heat source unit 5 is less than the permissible load of the second heat source unit 5, the fluid at the temperature T1 set in the temperature setting circuit 4 can be supplied from the pipe 7. Remove.

At the step port 6, it is determined that the temperature detected by the temperature detection element 0 does not reach the temperature T1 set in the temperature setting circuit 14. And outside, second fever &
This is when the load shared by the shrimp 5 exceeds the allowable load of the second heat source device 5. At 0S time L2 in Figure 3, the second
The allowable load of the heat source is expressed as L2-Ll. In such a case, in step 117, the other second heat source device 6 is activated and starts operating. In this way, when the shared load of the second silent source iso 6 is less than the allowable load of the second heat f2 iso 6, the temperature T1 set in the temperature setting circuit 15 is applied to the conduit 8 from the r52 heat rAt)16. It is possible to supply fluid with 0 (0).

In the aforementioned step n 4 , the temperature setting circuit 13
The temperature Tla set in is set to a value that allows the first heat source 8!1 to operate at approximately an allowable load, that is, at approximately full load. In this way, the first heat source device 1 performs almost full load operation, and therefore t52 heat v2? F15
．． The overall thermal efficiency during operation of the G can be improved.

When it is detected that the load 1 has decreased, and as a result, the temperature detected by the temperature detection element 9 corresponding to the first heat source device 1 has increased and reached the constant value T1b in step II IF. , in step n9, ff12 heat source 5.
6 is stopped, and only the first heat source device 1 is in operation.

For example, T la > T 1 b ・=(
1), or T1a=T1b-<2).

In the above-described embodiment, the load 4 is space heating, hot water supply, etc., but in other embodiments of the present invention, the load 4 may be air conditioning, etc. At this time, the temperature T1a described in +ii4 is set to a value less than the temperature T1. As a result, during cooling, etc., when the first heat source unit 1 and the second heat source unit 5, 6 are operated in parallel, the shared load of the first heat source unit 1 can be increased, and the overall thermal efficiency can be improved. I can do it.

When the first heat IF2 I'11.1 is a heat pump using a compression rock, the heat sources 5 and 6 may be a boiler as described above, or alternatively, a heat pump with such a compression rock. An absorption type refrigerating machine with lower thermal efficiency may also be used. When an absorption type refrigeration system is used as the first heat v2 machine 1, a boiler with lower thermal efficiency than such an absorption type cooling system can be used as the second heat unit 5, 6.

Effects As described above, according to the present invention, when performing parallel operation using the first heat rAtrd and the second heat source machine having a lower thermal efficiency, the first heat source machine with high thermal efficiency takes over the share. The load can be increased, thereby improving the overall thermal efficiency.

[Brief explanation of drawings]

Figure f51 is an overall block diagram of one embodiment of the present invention, the second
The figure is 7 for explaining the operation of the embodiment shown in Figure 1.
0-chart, FIG. 3 is a t-graph showing the state of load sharing. 1...1st heat source ((shaku, 2.3.7, 3...pipeline, 4...detector, 5,6...2nd heat source machine, 9,10...
11... Temperature detection element, 12... Processing circuit, 13,
14.15... Temperature Sorrow Agent Patent Attorney Number of strokes Keiichi Figure 1 Figure 3 Tsuki Rikan

Claims (1)

[Claims] The first heat source device includes a first heat source device and a second heat source device that has lower thermal efficiency than the first heat source device, and the first heat source device detects the outlet temperature of the fluid from the first heat source device. The second heat source device detects the outlet temperature of the fluid from the second heat source device and operates so that the outlet temperature becomes the predetermined first set value. The fluid from the first and second heat source machines is applied to the load, the first heat source machine is operated first, and the outlet temperature of the first heat source machine does not reach the first set value. 1. A method for controlling a plurality of heat source devices, comprising: changing a first setting value and activating a second heat source device so that the load shared by the first heat source device increases.