DE1523322B2 - ARRANGEMENT FOR GENERATING ANY TEMPERATURE IN A CLOSED TEMPERATURE VESSEL - Google Patents

Description

The temperature control vessel (12) is connected in a manner known per se to a supply line (14) which leads through a heat exchanger (13) and has a valve (7) controlled by the temperature regulator;
the temperature controller (2, 4) is a known electro-pneumatic program controller, to whose control pressure line for the pneumatic valve drives the storage vessel (12) is connected via the throttle point (9); and - ^ the temperature sensor is arranged in a pin line (1) of the temperature control vessel (12).

The invention relates to an arrangement for generating any time constant or variable Temperatures using a temperature control vessel at which the temperature control vessel has a supply line connected to a storage vessel for liquefied gas and the storage vessel via a line with a Throttle point connected to a compressed air source is and in which a valve is also provided in an exhaust air line behind the throttle point, which is of a Temperature controller is controlled depending on the control deviation in the temperature chamber.

To determine the temperature dependence of the visco-elastic properties of polymers, it is necessary to perform at closely spaced temperatures within a wide temperature range, for example, from -150 to + 18O ⁰ C or vice versa measurements. In the former case this can be done by bringing the specimen into a vessel whose temperature durph introducing yerdampfender liquid air to about - 180 was cooled ⁰ C - 190 °. If this vessel is left to stand at room temperature, the temperature in it will also rise continuously.

The rate of temperature rise can be determined by the choice of the thermal insulation layer and the thermal capacity of the vessel are affected. During this temperature rise you can continuously z. B. measure the torsional vibration behavior. A corresponding arrangement for carrying out this Measurement is z. B. in DIN-BIatt 53 445 of September 1959, p. 2, right column, is described.

After reaching room temperature, the temperature control is set with IiJJf? of a liquid circulation thermostat away. Au? the so. determined viscoelastic Properties one can draw important conclusions about the molecular structure, the crystallization ability etc. pull.

Up to now, the setting of the desired temperature within the large temperature interval mentioned above has presented enormous difficulties. Although one can - in the above-mentioned known arrangement, - the test chamber first of all with the aid of liquid nitrogen to about -18O ⁰ C to cool and then start the measurements. However, the temperature rise inside the test chamber does not take place at a constant rate. At first, the temperature will increase very quickly. However, the closer the temperature inside the chamber approaches room temperature, the slower the temperature rise will be. The temperature inside thus approaches room temperature asymptotically, as shown in FIG. 1 can be seen for times greater than 180 minutes (solid curve). (In Fig. 1, the solid curve is the temperature history at a cooling of a \ Temperiergefäßes from +20 to -148 ° C and the subsequent temperature rise again).

Now, however, the viscoelastic behavior depends in particular crystallizing polymers depend on - with '■ speed at which the temperature is varied. In order to achieve reproducible values at any time, it is necessary to regulate the temperature rise in such a way that it occurs within the entire temperature interval to be passed through, e.g. B. 1 ° C / min. amounts to.

Such a time-temperature dependency can be graphically represented as a straight line, as shown in FIG. 1 is indicated by the dashed line. This is the so-called linear temperature-time program. Also in this method, not a constant temperature rise of the thermal insulation and the heat capacity of Temperiergefäßes is guaranteed to 20 ⁰ C because above 25 ° C (1 g in point P i F.) Alone determine the further increase in temperature. The usual use of a liquid circulating thermostat above +20 ^{0 C brings the known ones.} Difficulties of two-substance systems £

regarding the necessary cleaning during the transition " from liquid to cold air. In addition, there is the “seam” at the transition from cold air on liquid to discontinuities in the temperature-time curve, which interfere with the measuring process.

The invention is based on a known arrangement for generating any time constant or variable Temperatures using a temperature control vessel at which the temperature control vessel over a supply line connected to a storage vessel for liquefied gas and the storage vessel via a line is connected with a throttle point to a compressed air source and furthermore in an exhaust air line a valve is provided behind the throttle point, which is dependent on a temperature controller is controlled by the control deviation in the temperature chamber.

The invention is based on the object of a measuring arrangement for a linear temperature-time program to create within the large temperature interval described above, which with the previously known arrangements or not. r cannot be implemented with the required accuracy leaves.

The arrangement according to the invention for solution 1 165 314 is described in which a liquid container

this task? is 'characterized by the combination with a pipe,' which is above the surface

nation of the following characteristics: the liquefied gas in the container leads to the Kammsr ^

a) "The temperature control vessel is in a manner known ^{per se, (l} > connection, stands. It_ is; further aV pressurized gas

with a supply line, which is provided by a heat ^{outlet 5} W ^ lIe which via a pipe with

, ..... , ^ö . at _t t is connected to the tank and above the liquid

exchanger leads and one from the temperature controller, ·. _,,. ·,, ··, ·, ... y- ■.

. . ,, ... t ■. UA speed ends, as well as a continuously changeable one

controlled valve has connected: - ,, ',, ju j- - ^ * λ

, sj π _t . . '. · Uu ι * Thermostat, which is controlled by the temperature of the

b) the temperature controller is a known _r , ... · ■. . »Γ _n . ·· ,,.

' ^{,, r} , ·? η ι j ■ ■ · Chamber is controlled and on the container

Electropneumatic program controller whose ·· r ■ ■■ η α ι * * ι ■ * j ♦ * σ ·· λ

"Ι JIi · ,. / ■■■ j ·; · L λτ _t -i ίο effective gas pressure controls progressively. For ar-

Control pressure line for the pneumatic valve ... ..,,,,,. ",, ,, _T,. . .

. . u jw * fn "u JIN wn work with alternating hot and cold air

drives the reservoir through the throttle j- _A j -ι .. laj j-

ι l · _t not the arrangement. Arrangements of this

is connected; or similar do not exhibit the versatility of

c) the temperature sensor is in an exhaust air line ... .. ",, _. . ,. ⁶ ,
j rr. · R- r> j * device proposed according to the invention.
of the Tempenergefäßes arranged. . _TT 5 j τ- · ι -j- t, jj ™ · ·

^{H 6 5} 15 Using the F1 g. 2 is the principle below

The invention is particularly characterized in that the control process is explained. That in the exhaust air

that with the help of the proposed arrangement a line thermocouple 1 supplies the elec-

linear decrease in temperature in the area below fresh part 2 of the electropneumatic controller

Room temperature down to -150 ° C is possible. thermal voltage corresponding to the actual temperature.

With the aid of the arrangement according to the invention, the programmer delivers the setpoint temperature

an extreme rise in temperature or a corresponding electrical voltage is also applied to the

- perform descent in linear form. To this electrical part of the regulator, the one with the difference

Purpose one leads alternately both voltages into the temperature control the pneumatic part 4 controls,

cold air from e.g. B. - 180 ⁰ C or hot air from z. B. The pneumatic part 4 is from the compressed air network 5,

400 ° C. By the rule 25 described below, the electrical part 2 from the electrical network

device can feed the supply line from cold or hot. The latter line is not shown in Fig. 2 -

Air can be adjusted so that a desired one is reproduced.
Set the temperature within a very short time. ^ If the actual temperature is too high at 1, then- ^ closes

In the invention, the flow of "up to the control air supplied by the pneumatic part 4

or cold air via lines into the tempering stream 6, the microvalve 7 for the hot air; - ^ r closes

vessel controlled. This control takes place with the help of a further the microvalve 8, so that the control air 6 over

single control device for both the hot and the pneumatic throttle 9 on the lifting system of the

for the cold air supply. Dewar 10 acts and liquid nitrogen through

The known arrangements require the cold air supply line 11 into the temperature control vessel 12

at all with the help of alternating hot and cold 35 promotes.

air work, each with separate control units. Known If the actual temperature is too low at 1, then it opens

Arrangements are also not for the mentioned control air flow 6, the microvalve 7, so that

suitable for large temperature ranges. So is z. B. by hot air that is generated in the heat exchanger 13,

British patent 843 732 describes an arrangement via the hot air supply line 14 into the temperature control vessel 11

when the air is at room temperature, a supply 40 passes. At the same time, the control air flow controls 6

container is removed. the microvalve 8, so that the throttle 9 passing

The gas flow divides into two lines, whereby air flow can escape into the open air at 15 and not

a heating device is installed in a line. acts more on the lifting system of the dewar vessel 10. At a certain point, the warm and the opening 15 also relieve the liquid

Cold air flows again, so that the action of the nitrogen is relieved from the pressure created by a constant

known arrangement basically consists in evaporation; in this state therefore hears

more or less large amounts of warm air from any supply of cold nitrogen into the temperature control

Cold air duct can be supplied. In such a vessel 12 on.

Arrangements arise when tem- If the actual temperature at 1 with the target tempe-

Temperatures above 100 ⁰ C generated in the temperature control vessel 50 corresponds to temperature 3, then the control air pressure is 6

should be. If there is a constant cold air just so large that the hot air valve 7 is closed

If electricity flows in, considerable disruptions occur. It is and the cold air valve 8 remains open, so that neither

It is therefore necessary for the valve provided to pass hot or cold air into the temperature control vessel 12 by hand, to readjust. The same difficulty arises with The programmer 3 guarantees an equal

the setting of lower temperatures, because again a moderate rise or fall in temperature (; hl ° C / min.)

manual adjustment is required. in the temperature control vessel. It is also possible to

The US patent specification 2,981,774 also means that the gram feed must be stopped at any point in time,

already an arrangement for setting any so that there is a constant in the temperature control vessel 12

Temperature adjusts in a relatively large temperature- temperature.

Interval has become known in which in a tube 60 F i g. 3 represents the measurement result of the temporal

a heating coil and a cooling coil are located, represents the temperature profile as the temperature rises.

which alternate in function. Otherwise T ₁ is the temperature of the thermocouple 1 in FIG. 2,

as in the present invention, a T ₀ is not the temperature inside the temperature control

Hot or cold air flow via separate lines vessel 12 in FIG. 2. Fig. 3 also shows that

led into a temperature control vessel. Also required 65 constant temperatures can be set. In

both the heating and the cooling coil, in the example shown here, the program was

disconnected regulator. A controller especially for low temperature of the programmer 3 in FIG. 2 after 60 minutes

turen is also switched off in the German exposition. F i g. 3 shows that T _{1 is} constant immediately

remains (T ₁ = -47 ⁰ C) and T ₀ also becomes constant (T ₀ = -52 ° C). After 120 minutes, the program feed was switched on again, whereupon the temperature rose again proportionally to the time. The program feed was switched off again after 210 minutes.

With the help of the arrangement according to the invention, measurements can be made at a constant temperature, z. B. to determine the tension-strain diagrams and to observe the torsional vibration behavior according to DIN 53 445, while the examined material is crystallizing.

1 sheet of drawings

Claims (1)

Claim: Arrangement for generating any time constant or variable temperatures below Use of a temperature control vessel in which the temperature control vessel is connected to a Connected storage vessel for liquefied gas and the storage vessel via a line with a Throttle point is connected to a compressed air source and also in an exhaust line a valve is provided behind the throttle point, which is dependent on a temperature controller is controlled by the control deviation in the temperature chamber, characterized by the combination following features: