JPH02192567A - Controller for cooling and heating regulating device - Google Patents

Abstract

PURPOSE:To prevent the frequent starting and stopping of a liquid supplying device, a compressor and a circulating pump, which is accompanied by the fluctuation of a liquid level, by a method wherein the compressor and the circulating pump are stopped when the liquid level of a liquid tank has become lower than a first set liquid level and the compressor as well as the circulating pump are operated when the liquid level has become higher than a second set liquid level higher than the first set liquid level while the liquid supplying device is operated when a liquid level, lower than a certain set liquid level, is continued for a predetermined period of time. CONSTITUTION:When the liquid level of a liquid tank has become higher than a second set liquid level L2, a float 35 is elevated and a lead switch 30 is closed. On the other hand, the reset signal of a FF circuit 58 in an operation control unit 46 is changed from 'H' into 'L', a transistor 59 is put OFF and the exciting of a relay 41 is released whereby the operations of a compressor, a circulating pump and the like are started. When brine is evaporated during the operation and the liquid level of the liquid tank becomes lower than a liquid level L2', the read switch 30 is opened. When a capacitor 66 is charged sufficiently thereafter, a relay 42 is excited and a solenoid valve is opened to start the supply of the liquid. When the liquid level is lowered further due to the leakage of the liquid or the like and the level has become lower than L1', the reed switch 31 is opened and the operations of the compressor, the circulating pump and the like are stopped.

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Field of Application) The present invention reduces the load of plastic molding molds, etc. installed at a distance from the main body of the device by using a cold and temperature-controlled prine (
This invention relates to a cooling and temperature control device used to maintain a predetermined temperature using water (water or liquid).

(b) Prior art The applicant has previously proposed a cooling/temperature control device of this type as shown in FIG. 9 (Japanese Patent Application No. 62-293239).

In Figure 1, (A) is a compressor (1), a condenser (2)
, a dryer (3), a kill pillar tube (4), an evaporator (5), and an accumulator (6) are successively connected in an annular manner to form a refrigerant circuit. ) is a brine circulation path that circulates and supplies brine to a load (9) such as a mold. Liquid tank (7)
is made of stainless steel with an open top, and the inside of the tank is vertically divided into an upper brine chamber (7a) and a lower brine chamber (7b) by a partition plate (11) having a liquid passage hole (10). The evaporator (5) is immersed in brine in the upper brine chamber (7a), and the heater (12) is inserted in the lower brine chamber (7b). Brine circulation path (
B) has an outgoing flow path (13) and a return flow path (14) between the load (9) and the liquid tank (7), and has a return flow path (14).
) has two branch passages (14) on the inlet side of the liquid tank (7).
a) It is branched into (14b). One branch path (14a) is connected to the upper brine chamber (7a), and the other branch path (14b) is connected to the lower brine chamber (7b). Also, the pipe diameter of the branch path (14b) is changed to the branch path (14b).
The pipe diameter is larger than that of 14a), and the branch path (14b)
By providing a resistor (15) in the brine chamber, the amount of brine flowing into the upper brine chamber (7a) and the lower brine chamber (7b) is appropriately adjusted. In addition, the inlet (16a) and first outlet (16b) of the three-way switching valve (16) are connected to the return flow path (14) upstream of these branch paths (14a) and (14b), so that the three-way switching valve (16) An air-cooled heat exchanger flow path (19) having an air-cooled heat exchanger (18) is connected between the second inlet (16c) of the switching valve (16>) and both branch paths (14a) and (14b). (20> is connected in parallel with the air-cooled heat exchanger (18), and the resistor (20) is connected in parallel with the air-cooled heat exchanger (18).
1〉 bypass pipe, (23) is a fan, (24)
is a control device, and a condenser (2) and an air-cooled heat exchanger (18) are juxtaposed in the air passage of the fan (23).

The control device (24) has a temperature sensor (25) that detects the pline temperature of the return flow path (14) and a room temperature sensor (26), and has a compressor (1), a circulation pump (8), a heater (1), and a room temperature sensor (26).
2), which controls the three-way switching valve (16) and the fan (23).

In the conventional apparatus described above, the brine temperature is increased from 15°C to 50°C.
When maintaining a predetermined temperature up to °C, the control device (24) operates the compressor (1), circulation pump (8), and fan (23), and switches the three-way switching valve (16) as shown by arrow A. In addition, the ON/OFF energization time of the heater (12) is linearly controlled according to the temperature detected by the temperature sensor (25).For this reason, the brine cooled in the upper brine chamber (7a) and the lower brine chamber (7b) are controlled linearly. ) is combined with the brine heated in the lower brine chamber (7b) to form brine at a predetermined temperature, which is then passed through the outgoing flow path (13) to the load (9).
sent to. In addition, the brine of the load (9) is passed through the return flow path (
14) and return to the upper brine chamber (7a) and lower brine chamber (7b) via the branch path (14a>(14b)).

In this way, the brine in the liquid tank (7) is loaded (
9), and the load temperature reaches a predetermined temperature (15 to 50
'C) maintained in the vicinity.

When maintaining the pline temperature at a predetermined temperature between 50°C and 90°C, the control device (24) stops the compressor (1), operates the circulation pump (8) and the fan (23), and also operates the three-way switching valve ( 16) as shown in the arrow. Further, the heater (1
2) On and off) Linearly control the energization time. Furthermore, the rotation speed of the fan (23) is controlled according to the temperature difference detected by the temperature sensor (25> and the room temperature sensor (26)), and when the temperature difference is large, the rotation speed of the fan (23) is decreased. At the same time, when the temperature difference is small, the rotation speed of the fan (23) is increased.Therefore, the brine flowing out from the liquid tank (7) flows through the outgoing flow path (13) - load (9) - three-way switching valve (16) - The temperature of the brine that flows through the air-cooled heat exchanger flow path (19), the bypass pipe (20) and the branch paths (14a) and (14b) in this order and returns to the liquid tank (7), and is supplied to the load (9), is air-cooled. The predetermined temperature (50~
90°C).

(c) Problems to be Solved by the Invention In the conventional apparatus described above, the liquid tank is open to the atmosphere, so the brine evaporates during use and the liquid level in the liquid tank decreases. Therefore, we installed a liquid level detector in the liquid tank,
When the liquid level drops below the set level, the liquid supply device is activated to replenish brine, and when the liquid level drops further, the compressor and circulation pump are stopped to protect the equipment. However, since the brine in the liquid tank is circulated to the load by a circulation pump, the liquid level in the liquid tank fluctuates up and down, causing the liquid supply device, compressor, and circulation pump to frequently start and stop near the set liquid level. was there. Especially during initial use, there is no brine in the brine circulation path.
In particular, the liquid level in the liquid tank fluctuated significantly due to the operation of the circulation pump.

This invention was made in view of the above facts,
The purpose is to prevent frequent starting and stopping of the liquid supply device, compressor, and circulation pump due to fluctuations in the liquid level due to the operation of the circulation pump.

(d) Means for Solving the Problems This invention includes a refrigerant circuit that connects a compressor, a condenser, a pressure reducing device, and an evaporator, a liquid tank in which the evaporator of this refrigerant circuit is immersed in brine, and Has a circulation pump,
In a cold temperature control device equipped with a brine circulation path that circulates brine to a load and a liquid supply device that supplies liquid to a liquid tank,
A liquid level detector that detects the liquid level in the liquid tank, and a liquid level detector that stops the compressor and circulation pump when the liquid level in the liquid tank becomes lower than the first set liquid level, and a liquid level detector that detects the liquid level in the liquid tank and stops the compressor and circulation pump when the liquid level in the liquid tank becomes lower than the first set liquid level. 2
The structure includes means for operating the compressor and circulation pump when the liquid level reaches a set level or higher, and means for operating the liquid supply device when the liquid level remains below a certain set level for a predetermined period of time M.

(E) When the liquid level in the working liquid tank becomes below a certain set level due to evaporation of brine or the like, the liquid supply control device (means) activates the water supply device after a predetermined time delay. Therefore, when the liquid level of the liquid tank is moving up and down near a certain set liquid level, the water supply device can be prevented from operating, and frequent activation and stopping of the water supply device can be prevented.

In addition, if the liquid level in the liquid tank decreases due to some abnormality and becomes lower than the first set liquid level, the operation control device (means)
The compressor and circulation pump are stopped and protected. At this time, even if the liquid level moves up and down near the first set liquid level, the compressor and circulation pump will resume operation unless the liquid level recovers to the second set liquid level, which is higher than the first set liquid level. This prevents these frequent starts and stops. In addition, when there is no brine in the brine circulation path, such as during initial use, the compressor and circulation pump will start operating when the liquid level in the liquid tank rises to the second set liquid level. Even if the liquid level in the liquid tank drops suddenly, the compressor and circulation pump can be prevented from stopping.

(f) Example Hereinafter, embodiments of the present invention shown in the drawings will be described.

FIG. 1 shows an example of a cooling and temperature control device to which the present invention is applied. In FIG. 1, parts common to those shown in FIG. 9 are given the same reference numerals.

In the cold temperature control device shown in FIG. 1, a liquid supply pipe (27) is connected to the upper part of a liquid tank (7), and a solenoid valve (28) is inserted into this liquid supply pipe (27). In addition, the liquid tank (
A liquid level detector (29) is provided at the upper part of the tank 7).

As shown in Figure 2, this liquid level detector (29) is a support rod (
32) and a pair of upper and lower floats (35) and (36) that are loosely fitted into this support rod (32) and whose downward movement is regulated by stop bars (33) and (34). (35) and (36) have magnets (37) and (38), respectively.
) is embedded.

FIG. 3 shows a schematic configuration of the control device (24). In Figure 3, (39) is the power switch, (40)
is a control unit, and relay contacts (411) (421) (431) are opened and closed according to the output signal of this control unit (40).
) (441)... by the solenoid valve (28), indicator lamp (45), compressor (1) and circulation pump (8)
etc. is controlled.

The control unit (40) includes an operation control device (
46) and a water supply control device (47) are built-in. The operation control device (46) includes resistors (47) (48), a reed switch (31), diodes (49) (50), an inverter (51), resistors (52) (53), and a diode (
54) and a capacitor (55).
1), an R-S flip-flop circuit (hereinafter referred to as FF circuit) (58), which is composed of two NAND circuits (56 bars 57) and to which the output voltage of the charge/discharge circuit (T1) is supplied as a set signal, and a transistor. (59) and a relay (41) that switches the relay contact (411). In addition, the water supply control device (47) has resistors (61) (62
), reed switch (30), and diode (63)
(64), an inverter (65), a capacitor (66),
A charging/discharging circuit (T2) consisting of resistors (67) (68) and diodes (69), resistors (70) (71), a NAND circuit (72), inverters (73) (74), and transistors ( 75), a relay (42) that opens and closes a relay contact (421), and diodes (63) (64).
) is supplied as a reset signal to the FF circuit (58).

When the liquid tank (7) is empty as in the initial use, the flow of the liquid level detector (29) (35) (36) is the second
In the state shown in the figure, the reed switch (30) (31)
are both open. When the power switch (39) is turned on, the input of the inverter (65) in the water supply control device (47) becomes 'H' and the output becomes 'L', as shown in Fig. 4, so that the capacitor (66) is charged in the direction shown through the resistor (67), and after a predetermined time, the NAND circuit (72)
The output of the solenoid valve (2) changes from "L" to "H".At this time, the transistor (75) turns on, the relay (42) is energized, and the relay contact (421) is turned on.
8) is opened and brine (for example, water) is supplied from the liquid supply pipe (27) to the liquid tank (inside). On the other hand, in the operation control device (46), the input of the inverter (51) is “H” and its output is “L”, so the set signal of the FF circuit (56) is “L” and its output is “H”. ” At this time, the transistor (75) turns on, the relay (41) is energized, and the relay contact (411) enters the normally open side, so the compressor (1), circulation pump (8), etc. start operating. Instead, the display lamp (45) lights up to notify you that it is in a standby state.

The liquid level in the liquid tank (7) rises to the first set liquid level Ll (
When the reed switch (31) turns on level) or higher,
The float (36) rises and the reed switch (31) closes. At this time, as shown in FIG. 5, in the operation control device (46), the input of the inverter (51) becomes "L" and its output becomes "H", and the capacitor (55) is connected via the resistor (52). It is charged in the direction shown. Then, after a predetermined period of time, the output voltage of the charge/discharge circuit (T1) changes from "L" to H. However, the FF circuit (58) has a reset signal of "H".
”, the output remains “H”,
The compressor (1), circulation pump (8), etc. are never able to run completely.

When the liquid level in the liquid tank (7) reaches or exceeds the second set liquid level L2 (on level of the IJ-do switch (30)), the float (35>) rises and the reed switch (30) closes. As shown in Figure 6, the water supply control device (47
), the input of the inverter (65) becomes "LIT" and its 'H' output is supplied via the resistor (68) and diode (69) to the NAND circuit (72). ) becomes “L”, and the transistor (
75) is turned off and the relay (42) is de-energized. At this time, the solenoid valve (28) closes and the liquid tank (7)
brine supply is stopped. In addition, a capacitor (6
The charge in 6) is the internal circuit of the inverter (65) and the resistor (68).
and is quickly discharged via the diode (69).

On the other hand, in the operation control device (46), the reset signal of the FF circuit (58) changes from "H" to "L", and its output changes to "
The transistor (59) is turned off and the relay (41) is deenergized.At this time, the relay contact (
421) enters the normally closed side, the compressor (1), circulation pump (8), etc. start operating. Brine in the liquid tank 7) is supplied to the brine circulation path (B) by operation of the circulation pump (8), and even if the liquid level in the liquid tank (7) drops rapidly, the FF circuit (58) maintains the liquid level. As long as the reed switch (31) does not open when the temperature drops below L1' (off level of the reed switch (31)), the output will not be reversed, so the compressor (1), circulation pump (8), etc. will repeatedly start and stop. Never.

During use, when the brine evaporates and the liquid level in the liquid tank (7) falls below L2' (off level of the reed switch (30)), the reed switch (30) opens.

However, the water supply control bag! (46), the reed switch (30) opens and the inverter (65)
) even if the output of
Even if the liquid level moves up and down and the reed switch (30) repeatedly opens and closes, the solenoid valve (28) will not repeatedly open and close.
When the capacitor (66) is sufficiently charged, the relay 42) is energized, the solenoid valve (28) opens, and liquid supply begins.

If the liquid level further decreases due to liquid leakage and falls below LL' (off level of reed switch <31)), the 8th
As shown in the figure, the reed switch (31) opens. At this time, the output of the inverter (51) becomes "L" in the operation control device (46), and the charge in the capacitor (55) is transferred to the diode (54) and the resistor. (53) and the internal circuit of the inverter (51), the set signal of the FF circuit (58) becomes L tl, the transistor (59) is turned on, and the relay (41) is excited. be done. Therefore, the compressor (1), the circulation pump (8), etc. are stopped, and the indicator lamp (45) is lit to notify of the abnormality. In this case, even if the reed switch (31) repeatedly opens and closes due to the up and down movement of the liquid level, the compressor (1), circulation pump (8), etc. does not start and stop repeatedly.

(G) Effects of the Invention Since the present invention is configured as described above, when the liquid level in the liquid tank decreases due to evaporation of brine, or when the liquid level further decreases due to liquid leakage, etc., the liquid level can be set. Even if the liquid moves up and down near the liquid level, it prevents the liquid supply device, compressor, and circulation pump from repeatedly starting and stopping, and especially when there is no brine in the brine circulation path during initial use. This is useful because it can prevent frequent starting and stopping of the compressor and circulation pump even when the liquid level fluctuates rapidly when the pump is operated.

[Brief explanation of the drawing]

Fig. 1 is a schematic configuration diagram showing an example of a temperature control device to which the present invention is applied, Fig. 2 is a structural explanatory diagram of a liquid level detector, Fig. 3 is an electric circuit diagram showing an example of a control device, and Fig. 4 8 to 8 are electric circuit diagrams for explaining the operation of the control section of the control device, and FIG. 9 is a schematic configuration diagram of a conventional cooling and temperature control device. (A)... Refrigerant circuit, (1)... Compressor, (2
)...Condenser, (4)...Capillary tube (
pressure reducing device), (5)...evaporator, (B)...brine circulation path, (7)...liquid tank, (8)...circulation pump, (9)...load, ( 24)...Control device, (27)...Liquid supply pipe, (28)...Solenoid valve (
liquid supply device), <29)...liquid level detector, (46)
...Operation control device (means), (47)...Water supply control device (means).

Claims (1)

[Claims] (1) It has a refrigerant circuit that connects a compressor, a condenser, a pressure reducing device, and an evaporator, and a liquid tank and a circulation pump in which the evaporator of this refrigerant circuit is immersed in brine, and circulates the brine as a load. In the cold temperature control device, which includes a brine circulation path that supplies liquid to a liquid tank, and a liquid supply device that supplies liquid to a liquid tank, there is provided a liquid level detector that detects the liquid level of the liquid tank, and a liquid level detector that detects the liquid level of the liquid tank that is lower than or equal to a first set liquid level. means for stopping the compressor and circulation pump when the liquid level reaches a second set liquid level higher than the first set liquid level, and for operating the compressor and circulation pump when the liquid level reaches a second set liquid level higher than the first set liquid level; 1. A control device for a cooling and temperature regulating device, comprising: means for operating a liquid supply device when the condition continues for a predetermined period of time.