JPH02195143A - Air conditioner - Google Patents

Abstract

PURPOSE:To make the air conditioning closely adjustable to heat load by providing a means whereby, in controlling the capacity of a heat source unit, the temperature of the hot air or cool air produced from the heat source unit is adjusted to the initially set value of temperature according to output signals of temperature from room thermostats. CONSTITUTION:The operation mode, that is, either cooling or heating, is selected by means of room thermostats 23; next, a desirable room temperature, that is, a set temperature Ts is set; than a step for starting the operation is taken. A control circuit 22 thereupon starts an outdoor unit 5 and also a blower 4 by driving an inverter 4b for the blower through the intermediary of an SC adjuster 4a. When the outdoor unit 5 is started, a refrigerating cycle is formed with an indoor heat exchanger 3 working as an evaporator in cooling or as a condenser in heating. During the cooling or the heating operation, the control circuit 22 finds the air-conditioning load (the difference between the room temperature and the set temperature for the room) for each room A, B, C so that the air supplied from a heat source unit 2 is controlled in amount by controlling the output frequency of the inverter circuit 4b for the blower according to the sum of the air-conditioning loads found as above.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to a duct-type air conditioner that air-conditions a plurality of rooms with one unit.

(Prior art) Some air conditioners are capable of guiding hot or cold air generated from a heat source device to multiple rooms through ducts, and can air condition multiple rooms with a single unit. Hot air control device in the branch of the duct distributing wind or cold air,
VAV (Variable Air Volume)
).

This air volume control device is equipped with a damper, and controls the opening degree of the damper, using human power to generate signals for the room temperature set by the room thermostat installed in each room and the detected room temperature. It is designed to determine the amount of wind.

(Problem to be Solved by the Invention) By the way, in an air conditioner equipped with the air volume control device as described above, a minimum air volume is set in order to maintain the necessary ventilation openings in each room during heating and cooling. It is controlled so that the following does not occur.

However, even if the heat load in each room increases and the air flow rate controller reaches its maximum, if the capacity of the heat source device is small relative to the heat load in each room, the temperature in the room will not reach the set temperature of the room thermostat. The problem arises that this is not the case. Furthermore, when the heat load in each room is smaller than the minimum capacity of the air volume control device, that is, when the capacity of the heat source device is large, a phenomenon occurs in which the room becomes too cold during cooling and too warm during heating.

This invention was made in view of the above-mentioned circumstances, and its purpose is to provide a means for correcting the initial set temperature value, and to control the capacity of the heat source equipment so that the corrected set temperature is achieved. To provide an air conditioner that can perform detailed air conditioning according to heat load by improving the phenomenon of not cooling during cooling and not heating during heating.

[Structure of the Invention] (Means and Effects for Solving the Problem) In order to achieve the above object, claim 1 provides a duct for distributing hot air or cold air generated from a heat source device to each room. An air volume control device is provided on a branch path to each room, and a room thermostat that outputs a temperature signal of each room is provided to this air volume control device, and the temperature output signal from the room thermostat is used to generate the temperature generated from the heat source device. comprising means for correcting the temperature of the wind or cold air with respect to the initial set temperature;
The ability of the heat source device is controlled so that the corrected set temperature is achieved.

Claim 2 provides an air volume control device that is controlled by a temperature output signal (Ta) from a room thermostat, wherein during cooling...when Ta>Ts+α, the set temperature is corrected to a certain temperature lower, and during heating...Ta<Ts-β. , the set temperature is corrected to a certain temperature higher, TS: set temperature a, β: a certain fixed temperature (Ta, Ts
, a, β>0) The ability of the heat source device is controlled so that the corrected set temperature is reached.

Claim 3 provides an air volume control device controlled by a temperature output signal (Ta) from a room thermostat, wherein during cooling...when Ta<Ts-α, the set temperature is corrected to a certain temperature higher, and during heating...Ta> When Ts+β is reached, the set temperature is corrected to a certain temperature lower, Ts: set temperature a, β: certain fixed temperature (Ta, Ts
, a, β>0) The ability of the heat source device is controlled so that the corrected set temperature is reached.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.

In Figure 1, 1 is a building, and there are multiple parts J? A.

It has B and C.

There is a variable capacity heat pump type heat source machine 2 in the building 1.
is installed. This heat source device 2 has an inlet 2a and an outlet 2b, and an indoor heat exchanger 3 is installed opposite the inlet 2a, and a variable capacity type is installed at a position corresponding to the outlet 2b. A blower 4 is installed.

A blower inverter 4b is connected to the blower 4 via an SC controller 4a, so that the air volume can be controlled arbitrarily, and the blower 4 is equipped with a blowout temperature sensor 4C.

Further, an outdoor unit 5 is installed outside the building 1, and an outdoor heat exchanger 6, a variable capacity compressor 7, and a compressor inverter 8 are installed inside the outdoor unit 5. The compressor 7 and the indoor heat exchanger 3 in the heat source device 2 are connected by a refrigerant pipe 9 to constitute a heat pump type refrigeration cycle.

Further, a blower 4 installed at the air outlet 2b of the heat source device 2
One end of a duct 10 is connected to the duct 10, and the other end of the duct 10 is connected to each room A via branch passages 11, 12 and 13.
, B and C. Said branch road 11.12.
13 have the same structure, so one of them will be explained as shown in FIG. That is, the screens 1 are provided on the upstream and downstream sides of the branch path 11.
4.14 is provided, and an air volume control device 1 is provided between these two.
5 is provided. This air volume control device 15 will be explained. 16 is a damper, and the opening degree of this damper 16 is controlled by a drive motor 17. On the upstream side of the damper 16, a wind speed sensor 20 consisting of a propeller 18 that rotates depending on the wind speed and a rotation speed detection element 19 that detects the rotation speed of the propeller 18 is provided, and a temperature sensor 21 is also installed. The detection signals of the wind speed sensor 20 and temperature sensor 21 are sent to the control circuit 22.
It is now entered into Furthermore, this control circuit 22 includes a room thermostat 2 installed in the room A.
The control circuit 22 receives a temperature output signal from the heat source device 3, and a control signal is also input to the SC controller 4a of the heat source device 2.

Therefore, hot air or cold air generated from the one heat source device 2 is guided to each room A%B%C via the branch path 11, 12, 13 of the duct 10, and the air volume control device 1
5 is controlled according to the heat load of each room ASB, C.

Next, the operation of the air conditioner configured as described above will be explained.

First, the cooling or heating mode is selected using the room thermostat 23, and then the desired room temperature is set.
That is, the set temperature Ts is set and the operation is started.

Then, the control circuit 22 starts the outdoor unit 5, and also starts the blower inverter 4b via the SC controller 4a.
to start the blower 4.

When the outdoor unit 5 is activated, a refrigeration cycle is formed, and the indoor heat exchanger 3 acts as an evaporator during cooling and as a condenser during heating. Then, due to the operation of the blower 4, air is sucked in through the suction port 2a, heat exchanged by the indoor heat exchanger 3, and then blown out into the duct 10 from the blowout port 2b.

This blown air is guided to branch paths 11, 12, and 13, and is supplied to rooms A, B, and C.

During this cooling or heating operation, the control circuit 22... calculates the air conditioning load (difference between the indoor temperature and the set indoor temperature) for each room A, B, and C, and controls the blower according to the sum of the calculated air conditioning loads. control the output frequency of the inverter circuit 4b. In other words, the amount of air blown from the heat source device 2 is controlled.

Furthermore, the control circuit 22 controls the opening degree of the damper 16 according to the air conditioning load of the corresponding room. In this case, each air volume control device 15... includes a wind speed sensor 20, a temperature sensor 21
The detection results are fed back and captured to set the optimal air volume. That is, during cooling operation, if the indoor temperature of room A is high, the opening degree of the damper 16 corresponding to that room is increased to increase the amount of air blown to section MA.

If the indoor temperature of room A is low, the opening degree of the damper 16 corresponding to that room is reduced, and the amount of air blown to room A is reduced.

Furthermore, when any one of all the air volume control devices 15 is fully opened by the damper 16 and the required air volume is insufficient, a command is sent to the SC controller 4a to increase the frequency of the blower inverter 4b, and When the dampers 16 of all the air volume control devices 15 are not fully open and the required air volume is satisfied, a command is sent to the SC controller 4a to lower the frequency of the blower inverter 4b. Further, the air outlet temperature sensor 4c detects the air outlet temperature, and sends a signal to the compressor inverter 8 of the outdoor unit 5 to control the frequency of the compressor 7 so that the air outlet temperature reaches the set outlet temperature.

However, when the heat load in each room ASB, C' is large, all the room thermostats 23... may not reach their set values. At this time, the capacity of the heat source device 2 is controlled by the means for correcting the initial set temperature Ts so that the corrected set temperature Ts is achieved.

FIG. 3 shows a flowchart for setting the outlet temperature of the heat source device 2, and shows the temperature output Ta from the room thermostat 23.
is detected, and in step 1 it is determined whether all the Tas are at the maximum air volume setting temperature value of the air volume control device.If YES, it is determined in step 2 whether or not the time has elapsed. If YES in step 2, proceed to step 3, determine whether it is cooling or heating, and if it is cooling, proceed to step 4, and Ta
>Ts+α. Here, Ts is a set temperature and α is a certain constant temperature. If YES in step 4, "correct the set temperature Ts lower by a predetermined value". In step 3, when heating is performed, proceed to step 5, and Ta<Ts-β
Determine whether Here, Ts is a set temperature and β is a certain constant temperature.

If YES in step 5, "correct the set temperature Ts higher by a predetermined value".

Also, if No in step 1, proceed to step 6,
It is determined whether each Ta is the minimum air volume setting temperature value of the air volume control device, and if YES, it is determined in step 7 whether or not the time has elapsed.

If YES in step 7, proceed to step 8, determine whether it is cooling or heating, and if cooling, proceed to step 9, and
Determine whether a<Ts-α. If YES in step 9, "correct the set temperature Ts higher by a predetermined value". When heating is performed in step 8, the process proceeds to step 10, and Ta>T
Determine whether s+β.

If YES in step 10, "correct the set temperature Ts lower by a predetermined value". Note that if No in steps 2 and 7, or No in step 4.5, return to step 1, and if No in step 7, or step 9.10.
If the answer is No, return to step 6.

Therefore, the heat load on each room A and BSC is large, and the temperature output signals (Ta) from all the room thermostats 23... do not reach the set temperature Ts of the room thermostats 23... in rooms A, B, and C. When, in other words, during cooling...Ta>Ts+α, the set temperature is corrected to a certain lower value, and during heating...Ta<Ts-β. Then, the set temperature is corrected to a certain temperature higher, and the capacity of the heat source device 2 is controlled so that the set temperature is reached after the correction.

Also, when the heat load is small, all air volume control devices 15
becomes the minimum air volume, and the temperature output signal Ta from all room thermostats 23... during cooling...Ta<
When Ts-α is reached, the set temperature is corrected to a certain temperature higher, and during heating...When Ta>Ts+β is reached, the set temperature is corrected to a certain temperature lower, and the heat source device 2 is controlled so as to reach the corrected set temperature.

Furthermore, even if there is only one temperature output signal Ta from the room thermostat 23, if Ta > Ts + β during cooling and Ta < Ts - β during heating, the set temperature of the cold air or hot air is returned to the initial set temperature.

In addition, although according to the said one Example, the case where there are three rooms was demonstrated, the number of rooms is not limited.

〔Effect of the invention〕

As explained above, according to the present invention, there is provided a means for correcting the temperature of hot air or cold air generated from the heat source device with respect to the initial set temperature based on the temperature output signal from the room thermostat, and the corrected set temperature Since we have controlled the capacity of the heat source equipment so that the heat load in each room changes, the temperature can be quickly returned to the set temperature, eliminating the phenomenon of not cooling during cooling or not warming during heating. It is possible to perform detailed air conditioning.

[Brief explanation of the drawing]

FIG. 1 is an overall configuration diagram of an air conditioner showing an embodiment of the present invention, FIG. 2 is a longitudinal sectional side view of the air volume control device, and FIG. 3 is a flowchart for setting the air outlet temperature of the heat source unit. 2...Heat source machine, 4...Blower, 10...Duct,
11-13... Branch road, 15... Air volume control device, 2
3...Room thermostat. Applicant's agent Patent attorney Takehiko Suzue

Claims (3)

[Claims] (1) A variable-capacity heat pump type heat source device that generates hot or cold air, a duct that distributes the hot or cold air generated from this heat source device to each room, a variable-capacity blower, and a variable-capacity blower that distributes the duct to each room. In the air conditioner, the air conditioner is equipped with an air volume control device provided in a branch path of the room, and a room thermostat provided in each room and outputting a temperature signal to the air volume control device. An air system characterized by comprising means for correcting the temperature of hot air or cold air generated from the heat source device with respect to an initial set temperature, and the capacity of the heat source device is controlled so that the temperature reaches the corrected set temperature. harmonizer. (2) Temperature output signal from room thermostat (Ta
) Air volume control device controlled by odor cooling...Ta>
When Ts + α is reached, the set temperature is corrected to a certain temperature lower, and during heating... When Ta < Ts - β, the set temperature is corrected to a certain temperature higher, Ts: set temperature a, β; a certain fixed temperature (Ta, Ts, α , β>0) The air conditioner according to claim 1, wherein the capacity of the heat source device is controlled so that the corrected set temperature is reached. (3) Temperature output signal from room thermostat (Ta
), when cooling...When Ta<Ts-α, the set temperature is corrected to be higher by a certain temperature, and during heating...When Ta>Ts+β, the set temperature is corrected to be lower by a certain temperature, Ts; Set temperature α, β; certain constant temperature (Ta, Ts, α, β>0) The capacity of the heat source device is controlled so that the corrected set temperature is achieved. air conditioner.