JPH0195269A - Cold temperature regulator - Google Patents

Abstract

PURPOSE: To keep the brine temperature quickly at a set level even when it is set at a high level by comparing the brine temperature in a brine circulation path with a set level and delivering a ON command to a chiller when an OFF command is delivered for the first time. CONSTITUTION: Brine is supplied from a liquid tank 7 to a load 12, e.g. a die, using a circulation pump 11 and branched into two systems on the return side after exchanging heat with the load 12 before being fed to the upper and lower sections of a tank. Temperature of the going or returning brine is detected by a temperature sensor 15 and a chiller A is operated through a controller 16 which also turns a heater 8 on/off to regulate the brine temperature thus keeping the temperature of the load 12 at a constant level. In case of a high set temperature, operation of the chiller A is started when the brine temperature reaches the set temperature and an OFF command is delivered for the first time from a heater control means. Consequently, the brine temperature rises quickly to the set level and then the set temperature is sustained quickly by turning the heater 8 on/off.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Industrial Application Field The present invention reduces the load on plastic molds, etc. installed at a distance from the main body of the device by using cool 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) Conventional technology Conventionally, as this type of cooling and temperature control device, for example,
As disclosed in Publication No. 15107, brine is stored and supplied to the load via a cooling system that connects a refrigerant compressor, an evaporator, etc. to form a refrigeration cycle, and a brine circulation path that connects a circulation pump. Equipped with a liquid tank to
A liquid cooling device is known that cools brine by accommodating an evaporator in a liquid tank.

(8) Problems to be Solved by the Invention The liquid cooling device described above cannot be used for a load that requires maintaining a temperature higher than room temperature, such as a mold for plastic molding. Of course, if a heater is installed inside the liquid tank and the brine temperature is adjusted using both the heater and the evaporator, it is possible to control the load temperature over a wide range, but if the brine temperature is too high (e.g. 40°C or higher) ), the heating amount of the heater and the cooling amount of the cooling device are balanced, and it takes time for the brine temperature to reach the set temperature, causing a problem that the start of use of loads such as molds is delayed. Ta.

This invention was made in view of the above facts,
To rapidly maintain brine temperature at a set temperature even when the brine temperature is set to a high temperature.

(d) Means for Solving the Problems This invention includes a cooling system that connects a refrigerant compressor, an evaporator, etc. to form a refrigeration cycle, and a brine supply system that supplies brine to a load through a brine circulation path having a circulation pump. In a cold temperature control device having a liquid tank for storing liquid and housing an evaporator and a heater in the liquid tank, the brine temperature in the brine circulation path is compared with a set temperature, and the heater is turned on.
This configuration includes a control device having a heater control means that issues an OFF command, and a cooling device control means that issues an ON command to the cooling device when the heater control means issues an OFF command for the first time.

(*) Effect With this configuration, if the set temperature is set high, the cooling device will remain in operation from the time the equipment starts operating until the brine temperature reaches the set temperature and the heater control means issues an off command. Since it is not activated and only heating is performed by the heater, the brine temperature is rapidly maintained at the set temperature.

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

In Figure 1, (A) represents a refrigerant compressor (1), a condenser (
2), a fan (3), a dryer (4), an evaporator (5) formed of a coiled steel pipe, and an accumulator (6), and is a cooling device that constitutes a refrigeration cycle. The evaporator (5) is located in the upper part of a liquid tank (7) made of stainless steel or the like with an open top, and a heater (8) is installed in the lower part of the liquid tank (7) to adjust the brine temperature.
> is provided. In addition, the evaporator (5) and heater (8
) is provided with a partition plate (1) having a circular liquid passage port (9).
0), the inside of the tank (7) is divided into an upper brine chamber (7A) and a lower brine chamber (7B). (B) is a brine circulation path, in which the brine of the liquid tank (7) of the device body is separated from the outlet (73) by using the circulation pump (11) provided inside the device, and is loaded with molds, etc. (12) via a manual valve (13), and the brine that has undergone heat exchange with the load (12) is returned to the inside of the apparatus via a manual valve (14).

The brine circulation path (B) branches into two systems on the return side, and is connected to a first inlet (71) and a second inlet (72) by a tank upper return vibe (20) and a tank lower return vibe (21), respectively. It is designed to flow into the upper part of the tank and the lower part of the tank through the tank.Tank upper return vibe (20)
The pipe diameter of the tank is made smaller than that of the tank lower return vibe (21), and a resistor (2) is installed inside the tank lower return vibe (21).
By adjusting the setting of 2), the amount of brine flowing into the upper part of the tank is restricted. The brine that has flowed into the upper brine chamber (7A) is cooled by the evaporator (5), passes through the liquid passage port (9) of the tank partition plate (10), and flows into the lower part of the tank, resulting in two streams of brine. merge. Further, the returning (or going) temperature of the brine is detected by the temperature sensor (15), and the control device (16) operates the cooling device (A), turns on the heater (8),
By controlling off the brine temperature (e.g. 15-5
0″C) to keep the temperature of the load (12) outside the device constant with high accuracy.Manual valve (17),
(18) are for draining the circulation pump (11) and liquid tank (7), respectively. Also, the reference water level (19) in the tank (7) is set so that the evaporator (5) is completely submerged.

In addition, the circular liquid passage port (
By appropriately changing the diameter of brine (9), it is possible to adjust the flow rate near the port (9) where brine flows from the top of the tank to the bottom of the tank, allowing it to flow from the top of the tank to the bottom of the tank at a certain flow rate. By doing so, it is possible to prevent high-temperature brine from flowing from the lower part of the tank to the upper part of the tank, and to prevent an excessive rise in temperature of the brine in the upper brine chamber (7A).
) can promote efficient heat exchange. In this example, the cooling capacity of the cooling device (A) is 1800 kcal
/h, and the capacity of the heater (8) is 3KW.

FIG. 2 is an electrical circuit diagram of the control device (16), which includes a heater control means (C) and a cooling device control means (D).

The heater control means (C) has a comparator (23) that issues an on/off command to the heater (8).A temperature sensor (1)
5) exhibits negative resistance characteristics, and the resistance value decreases as the brine temperature increases. Further, the brine temperature is set with a variable resistor (24), and is used as a positive input of a comparator (23). When the negative input potential of the comparator (24) exceeds the positive input potential, the output of the comparator (23) becomes "L", turning off the transistor (25).

At this time, the normally open contact (261) of the first relay (26) is turned off to de-energize the heater (8). When the brine temperature decreases, the contacts (261) of the relay (26) turn on,
The brine temperature is increased by a heater (8).

In this way, the heater (8) is controlled on and off so that the brine temperature can be maintained at the set temperature.

The cooling device control means (D) includes an initial setting circuit (27) and 1;
R-S Philip flop (28) and a transistor (29) for operating the cooling device (A) when the comparator (23) of the heater control means (C) issues an off command (“L” output) and a relay (30).

When the operation switch (31) is turned on, as shown in FIG.
) is supplied with a set input ``L''. At this time, assuming that the brine temperature is lower than the set temperature and the comparator (23) is emitting an H" output, the Philip prop (25
) output Q becomes "L". For this reason, the transistor (
29) and relay (30) are turned off and the normally open contact (3
01) is turned off and the compressor (1) and blower (8) are not operated. The initial setting circuit (27) inverts its output in a certain period of time (for example, 0.5 seconds) by a time constant circuit of a capacitor (32) and a resistor (33), and sets the set input to "H". After that, when the brine temperature exceeds the set temperature and the comparator (23) issues an off command ("L" output) for the first time, the reset input becomes "L" and the output Q becomes "H".
to be reversed. Therefore, the transistor (29) is turned on, and the compressor (1) and the blower (3) are energized via the contact (301') of the relay (30). Thereafter, even if the reset input changes with the ON/OFF control of the heater (8), the output Q remains 'H'. Also, at the same time as the operation switch (31) is turned on, the heater control means (C) When the OFF command is issued, as shown in FIG. 4, the output Q of the flip-flop (28) is kept at 'H' from the beginning, and the cooling device (A) starts operating from the beginning. In addition, (34) is an alternating current, (35) is a step-down transformer, and (36) is a direct current constant voltage circuit.

According to this embodiment, when the set temperature is set to a high value (for example, 45° C.) by the variable resistor (23), the brine temperature reaches the set temperature and the heater control means (C) first issues an off command. When this occurs, the cooling device (A) starts operating. Therefore, the brine temperature rapidly rises to the set temperature, and thereafter can be maintained at the set temperature by controlling the heater (8) on and off. Of course, when the brine temperature is set to a temperature lower than room temperature (for example, 15°C), the cooling device (A) is activated by turning on the operation switch (31),
They start working at the same time.

(G) Effects of the Invention Since the present invention is configured as described above, when the brine temperature is set to a high value, the brine temperature reaches the set temperature from the start of operation, and the heater control means is turned off first. Until a command is issued, the cooling device is not activated and only heating is performed by the heater, and the brine temperature can be rapidly maintained at the set temperature regardless of the temperature setting. Ideal for maintaining a load at a specified temperature.

[Brief explanation of the drawing]

Fig. 1 is a schematic configuration diagram of a cooling and temperature control device showing an embodiment of the present invention, Fig. 2 is an electric circuit diagram of a control device, Fig. 3 is an explanatory diagram of input/output waveforms of a phillip flop, and Fig. 4 is a diagram of another example. This is an explanatory diagram of input/output waveforms under input conditions. (A)...Cooling device, (B)...Brine circulation path, (C)...Heater control means, (D)... Cooling device control means, (1)...refrigerant compressor, (5)...
- Evaporator, (7)...liquid tank, (8)...heater, (12)...load, (16)...control device.

Claims (1)

[Claims] (1) It has a cooling device that connects a refrigerant compressor, an evaporator, etc. to form a refrigeration cycle, and a liquid tank that stores brine to be supplied to the load via a brine circulation path having a circulation pump, and the liquid In a cooling and temperature control device in which an evaporator and a heater are housed in a tank, there is a heater control means that compares the brine temperature in the brine circulation path with a set temperature and issues an on/off command to the heater, and this heater control means first. 1. A cooling and temperature control device comprising: a cooling device control means for issuing an ON command to the cooling device when an OFF command is issued to the cooling device.