JPH02192566A - 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 and supply brine quickly by a method wherein the liquid supplying device is operated when the liquid level of a liquid tank is lower than a first set level for a first predetermined period of time while the compressor and the circulating pump are operated when the liquid level, lower than the first set level and higher than a second set level, is continued for a second predetermined period of time. CONSTITUTION:In a first timer 45, the output of a NAND circuit 54 attains 'H' until a capacitor 53 is charged and a predetermined period of time has elapsed while the output 'L' of another NAND circuit 69 is supplied to the input side of an inverter 58, and therefore, a solenoid valve 28 is opened and brine is supplied from a liquid supplying pipe 27 into a liquid tank 7. When the liquid level of the liquid tank 7 rises to a level higher than a second set liquid level S2, the output of another inverter 64 attains 'L' in a second timer 46 and another capacitor 68 is charged. When a predetermined period of time has elapsed after a time when a lead switch 31 is put OFF, the output of the NAND circuit 69 attains 'H' and the operations of a compressor 1, a circulating pump 8 and the like are started.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Industrial Application Field The present invention reduces the load of plastic molding molds, etc. installed at a location away from the main body of the device by using cold and temperature-controlled brine (
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. 5 (Japanese Patent Application No. 293239/1982).

In Figure 1, (A) is a compressor (1), a condenser (2)
, a refrigerant circuit formed by sequentially connecting a dryer (3), a capillary tube (4), an evaporator (5) and an accumulator (6) in an annular manner. This is a brine circulation path that circulates and supplies brine to a load (9) such as a mold. Liquid tank (7)
The tank 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). Prine 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 prine 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). has been done. In addition, (20) is connected in parallel with the air-cooled heat exchanger (18), and the resistor element 2
1) a bypass pipe with (23) 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 s
To maintain a predetermined temperature up to o'c, the control device (24) operates the compressor (1), circulation pump (8>, and fan (23)), and also operates 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 prine cooled in the upper brine chamber (7a) and the lower brine chamber ( 7b> is merged with the prine heated in the lower brine chamber (7b) to form the prine at a predetermined temperature, and the prine is transferred to the load (9) through the forward flow path (13).
). Moreover, the prine of the load (9) returns to the upper brine chamber (7a) and the lower brine chamber (7b) via the return flow path (14) and branch paths (14a) and (14b). In this way, the prine of the liquid tank (7) is circulated and supplied to the load (9), and the load temperature is maintained at a predetermined temperature (15 to 5
0°C).

When maintaining the brine temperature at a predetermined temperature between 50°C and 90°C, the controller (24) stops the compressor (1);
The circulation pump (8) and fan (23) are operated, and the three-way switching valve (16) is switched as indicated by the arrow.

In addition, the heater (
12) Linearly control the on/off 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. , when the temperature difference is small, the rotation speed of the fan (23) is increased. Therefore, the pline flowing out from the liquid tank (7) is routed through the forward flow path (13) - load (9) - three-way switching valve (16) - air cooling. The temperature of the pline, which flows through the flow path (19) for the type heat exchanger and the bypass pipe (20) - branch paths (14a) and (14b) in this order and returns to the liquid tank (7) and is supplied to the load (9), is set to the air-cooled type. The predetermined temperature (50
~90°C).

(c) Problems to be Solved by the Invention In the conventional device described above, the liquid tank is open to the atmosphere, so the prine evaporates during use, causing the liquid level in the liquid tank to drop. Therefore, we installed a liquid level detector in the liquid tank,
When the liquid level drops below the set liquid level, the liquid supply device is activated to replenish the pline, and when the liquid level drops further, the compressor and circulation pump are stopped to protect the equipment. However, since the liquid tank's pline 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.

This invention was made in view of the above facts,
This prevents frequent starting and stopping of the liquid supply device, compressor, and circulation pump when the liquid level is near the set liquid level, and also ensures that liquid is quickly supplied to the pline when there is no pline in the liquid tank. The purpose is to

(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 can be immersed in brine, and a circulation system. In a cold temperature control device that includes a pump, a brine circulation path that circulates brine as a load, and a liquid supply device that supplies liquid to a liquid tank, a liquid level detector that detects the liquid level of the liquid tank, and a liquid tank. means for activating the liquid supply device when the liquid level is below a first set liquid level for a first predetermined period; and a second liquid level lower than the first set liquid level.
This configuration includes means for operating the compressor and the circulation pump when the liquid level continues to be equal to or higher than the set liquid level for a second predetermined period of time.

Further, in the present invention, the above-mentioned control device for the cooling and temperature control device is configured to include means for prohibiting the delay operation of the means for operating the liquid supply device when the liquid level in the liquid tank is lower than the second set liquid level. .

(e) When the liquid level in the working liquid tank becomes lower than the first set liquid level due to evaporation of brine or the like, the first timer (means) operates the water supply device after a predetermined time delay. Therefore, when the liquid level of the liquid tank is moving up and down near the first set liquid level, the water supply device can be prevented from operating, and frequent starting and stopping of the water supply device can be prevented.

Further, when the liquid level of the liquid tank decreases due to some abnormality and becomes lower than the second set liquid level, the compressor and circulation pump are stopped to protect them. At this time, even if the liquid level moves up and down near the second set liquid level, the second timer (means) prevents the compressor and circulation pump from operating immediately, preventing their frequent starting and stopping. be done.

Furthermore, by providing means for prohibiting the delay operation of the first timer (means) for operating the liquid supply device when the liquid level of the liquid tank is lower than the second set liquid level, the liquid tank can be used as in the initial use. When there is no brine in the tank, brine is quickly supplied.

(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. 5 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 the 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 stoppers (33) and (34). Magnets (37) and (38) are attached to 35 and 36, 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) (43) are opened and closed according to the output signal of this control unit (40).
1) (441)... by solenoid valve (28),
Energization of the compressor (1), circulation pump (8), etc. is controlled.

As shown in FIG. 4, the control section (40) includes two timers (45) and (46). First timer (
45) are resistors (47) (48) and reed switch (3
0), inverter (49), resistor (50) (51), diode (52), capacitor (53), NAND circuit (54), resistor (55) (56) (57), inverter It is composed of a resistor (58), a resistor (59) (60), a transistor (61), and a relay (41) that opens and closes a relay contact (411). Also, the second timer (4
6) are resistors (62) (63) and reed switch (31)
), inverter (64), resistor (65) (66), diode (67), capacitor (68), NAND circuit (69), resistor (70) (71), inverter (72)
, resistors (73) (74), a transistor (75), and a relay (42) that opens and closes a relay contact (421).In addition, an inverter (58) of the first timer (45) A latch circuit (inhibiting means) in which the input side of the NAND circuit (69) and the output side of the NAND circuit (69) have a diode (76).
(77).

When the liquid tank (7) is empty as in the initial use, the float (35) < 36) of the liquid level detector (29) is in the state shown in Fig. 2, and the reed switch (30) (31) are both closed. When the power switch (39) is turned on, the second timer (46) changes the input of the inverter (64) to “
Since the high output is input to the NAND circuit (67) via the resistor (66) and diode (67), the output of the NAND circuit (69) becomes low.

At this time, the output of the inverter (72) becomes "H", the transistor (75) is turned on, and the relay (42) is excited. Therefore, the relay contact (421) opens and the compressor (1), circulation pump (8), etc. do not operate. -Bj1 In the first timer (45), the output of the inverter (49) is "H", and the capacitor (53) is charged via the resistor (50). Therefore, the output of the NAND circuit (54) remains H'' until the predetermined time elapses.
Since the "L" output of the NAND circuit (69) is fully supplied to the input side of the inverter (58) via the latch circuit (77), the output of the inverter (58) becomes "H" and the transistor ( 61) is turned on and the relay (41) is excited. Then, the solenoid valve (28) is connected to the relay contact (411).
) is energized, the solenoid valve (28) opens, and the liquid supply pipe (27)
A prine (for example water) is supplied into the liquid tank (7) from.

When the liquid level of the liquid tank (7) rises and becomes equal to or higher than the second set liquid level L2, the float (36) rises and the reed switch (31) opens. At this time, in the second timer (46), the output of the inverter (64) becomes "L", and the capacitor (68) is charged via the resistor (65) and the internal circuit of the inverter (64). Because it is done, NAND circuit (69)
The potential of one input terminal of the transistor (75) gradually decreases, and when a predetermined period of time has elapsed since the reed switch (31) was turned off, the output of the NAND circuit (69) becomes "H" and the transistor (75) turns off. At this time, the relay (42) is de-energized and the relay contact (421) closes, so the compression is 1! (1), circulation pump (8), etc. start operating. In this way, when the liquid level in the liquid tank (7) rises to L1 or higher, the compressor (1), circulation pump (8), etc. are operated after a predetermined time delay. (8) operation, the liquid tank (7)
) Even if the liquid level moves up and down, there is no need to worry about the compressor (1), circulation pump (8), etc. starting or stopping frequently. Also, when the output of the NAND circuit (69) becomes “H”, the latch circuit (77
) is released, but before that the NAND circuit (5
Since the output of transistor (4) is L'', the output of transistor (6
1) remains on, and the liquid supply to the liquid tank (7) continues as it is.

When the liquid level in the liquid tank (7) exceeds the first set liquid level L1, the reed switch (30) opens and the first timer (45
), the output of the inverter (49) becomes "L".

At this time, the charge of the capacitor (53) is transferred to the diode (5
2) and the resistor (51), the output of the NAND circuit (54) becomes 'H'. Therefore, the transistor (61) is turned off and the relay (41) is de-energized. The solenoid valve (28) closes and the brine supply ends.

During use, when the brine evaporates and the liquid level in the liquid tank (7) falls below L1, the reed switch (30) closes.

However, in the first timer (45), the relay (41) is not energized immediately even after the reed switch (30) is closed, so the liquid level in the liquid tank (7) moves up and down due to the operation of the circulation pump (8). Even if the reed switch (30) repeats opening and closing, the valve (28) does not repeat opening and closing. When the capacitor (53) is sufficiently charged, the relay (41) is energized and the solenoid valve (28
) opens and fluid supply begins.

When the liquid level further decreases due to liquid leakage and becomes below L2, the reed switch (31) closes and the second timer (
46), the relay (42) is immediately excited, and the compressor (1), electromagnetic pump (8), etc. are stopped.

In this case, the reed switch (31
) repeatedly opens and closes, it takes time to charge the capacitor (68), so the relay 42) remains energized, and the compressor (1) and electromagnetic pump (8) do not start and stop repeatedly. , these can be protected.

(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 the line, or when the liquid level further decreases due to liquid leakage, the liquid level can be set. Even if the liquid moves up and down near the liquid level, the liquid supply device, compressor, and circulation pump can be prevented from repeatedly starting and stopping, and these can be protected.

Furthermore, by providing a means for prohibiting the delay operation of the first timer when the liquid level in the liquid tank is lower than the second set liquid level, brine can be supplied when there is no brine in the liquid tank, such as during initial use. It can be started quickly and is easy to use.

[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 5 is an electric circuit diagram showing the internal configuration of the control section of the control device, and FIG. 5 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, (
45)...first timer (means), (46)...
Second timer (means), (77)...Latch circuit (
Prohibited means).

Claims (2)

[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, 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 for a first predetermined period of time. means for activating the liquid supply device when the liquid level is below a first set liquid level; and means for operating the compressor and circulation pump when the liquid level continues to be at or above a second set liquid level lower than the first set liquid level 1. A control device for a cooling and temperature control device, comprising a means for activating it. (2) A control device for a cooling and temperature regulating device, comprising means for inhibiting delay operation of a means for operating a liquid supply device when the liquid level in the liquid tank is lower than a second set liquid level.