WO2016036272A1

WO2016036272A1 - Method for cooling the lid of a water bath of a research or testing device

Info

Publication number: WO2016036272A1
Application number: PCT/RU2015/000065
Authority: WO
Inventors: Алексей Евгеньевич ДЕНИСОВ; Игорь Николаевич НИКУЛИН
Original assignee: Общество с ограниченной ответственностью "Биофизическая аппаратура"
Priority date: 2014-09-02
Filing date: 2015-02-04
Publication date: 2016-03-10
Also published as: SE541677C2; RU2568941C1; SE1651741A1; CN106659946A

Abstract

The invention relates to the field of testing and research. A method for cooling the lid of a water bath of a research or testing device consists in passing a pressurized flow of a cold liquid agent through the lid of a water bath of a research or testing device, and in evacuating said agent. In order to feed a pressurized flow of cold liquid agent, a stand-alone liquid cooling unit is used, said unit circulating a cooling agent in a closed loop. A flow of cold liquid agent is passed through a tube or tubes, positioned in a steam discharge cavity of a lid or under the lid in a boiling water steam condensation zone, the agent being evacuated under pressure via at least one radiator of the stand-alone liquid cooling unit having a ventilator in order for the agent cooled in the radiator subsequently to be fed under pressure into the cavity of the tube or tubes.

Description

Method for cooling a water bath cover of a research or testing device

The invention relates to the field of testing and research, and relates to a method of cooling the lid of a water bath of a research or testing device based on the use for testing or research of materials, compositions and compositions or mixtures of a water heating bath.

The present invention is considered on a specific example of a research device for controlling the quality of grain crops by alpha-amylase activity, which can be used in bakery, bakery, agricultural enterprises, grain processing enterprises, as well as in other processing industries. Such a device for monitoring the quality of crops by alpha-amylase activity is described in TU 4215-006-172147768-98, Device for determining the number of falls, ППП-3. This decision was made as a prototype for the claimed method.

This research device contains a water bath in a casing with a lid. A level indicator is installed on the casing of the water bath to visually monitor the water in the bath. The lid of the water bath contains slots for installing a cassette with tubes and a vapor chamber with a built-in water cooling loop. For research, fill the water bath with distilled water through the hole for the tubes and check the water level in the bath according to the level indicator installed on the casing of the bath, and which should be in the middle of the drain pipe zone. The tubes are washed, rinsed with distilled water, dried and installed in cassettes. They turn on the device in the network, above the water bath there is an indicator on which the inscription on the indicator changes when the required temperature is reached. Place in each tube a weighed portion of ground grain or flour and pour distilled water into them at room temperature. Close the tubes with rubber stoppers and shake them until a homogeneous suspension is obtained. Tubes with a suspension (without rubber plugs) are installed in a stand with a cassette and lowered into nests made on the lid of the water bath. Test tubes with suspension are heated in a water bath, which leads to the conversion of the suspension into a paste. After that, the mixers are lowered into the tubes in free fall, which, under their own weight, begin to fall down. The duration of the fall of the rod-mixers is determined by the viscosity of the paste, depending on the activity of alpha-amylase, thinning the paste. The fall of each of the rod-mixers continues until the corresponding sensor of the lower position, which stops the time counting on its channel, is triggered. The fall time of the stirring rod in a gelatinized water-flour suspension will be the determined fall number.

In order for water to not boil out of the water bath, the lid of the bath should be cooled. For this, flow cooling is used. The need for cooling is due, firstly, to exclude the formation of excessive vapor pressure and their evaporation into the environment (solving the safety of experiments or studies), and secondly, to ensure the preservation of the initial conditions for heating to exclude inhomogeneity of heating of the tubes along their height (with the purpose of providing the same conditions for different series of experiments and studies of the same material or different materials or mixtures).

However, the use of flow cooling requires a large flow of water, and there is no possibility of controlling the degree of cooling itself. Excessive cooling will increase time for boiling water in a water bath and the temperature of the water itself, and with insufficient cooling, evaporation increases, which leads to a decrease in the volume of water and the need for topping it up.

To ensure guaranteed retention of the conditions for heating water in a water bath and its quantity, it is necessary to use a cooling system that would be temperature-controlled in synchronization with the volume of water in the water bath, which would preserve the process of boiling water with a sharp decrease in its flow rate (except for natural evaporation / drying, not caused by the process of vaporization from boiling).

The present invention is aimed at achieving a technical result consisting in increasing water independence and resource saving by eliminating the need for replenishment of water in a water bath and increasing the controllability of the degree of cooling in synchronization with the process of boiling water in this bath.

The specified technical result is achieved by the fact that in the method of cooling the lid of a water bath of a research or test device, which consists in passing under pressure a stream of a cold liquid agent through a lid of a water bath of a research or testing device and draining this agent, an autonomous autonomous liquid is used to supply a pressure of a stream of cold liquid agent liquid cooling unit with circulation of the cooling agent in a closed loop, and the flow of cold liquid agent is passed through a tube or tubes placed in the vapor outlet cavity of the lid or under the lid in the condensation zone of boiling water vapor to ensure that this agent is drained under pressure through at least one radiator with a fan of an autonomous liquid cooling unit for subsequent supply under pressure of the agent cooled in the radiator into the tube cavity or tubes. These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

The present invention is illustrated by specific examples.

5 performance, which, however, are not the only possible, but clearly demonstrate the ability to achieve the desired technical result.

In FIG. 1 is a block diagram of a cooling system of a lid of a water bath of a research or test device.

According to the present invention, an energy-saving and water-saving method for cooling the lid of a water bath of a research or testing device is considered. Moreover, this method allows you to control the process of maintaining the boiling water in the water bath of the device due to the synchronization of the degree of cooling and the process of boiling water in a closed volume.

A method of cooling the lid of a water bath of a research or test device consists in passing under pressure a stream of cold liquid agent through the lid

20 water baths of a research or testing device and draining this agent. At the same time, a stand-alone liquid cooling unit with a circulation of a cooling agent in a closed loop is used to supply a stream of cold liquid agent under pressure.

25 The flow of a cold liquid agent is passed through a tube or tubes placed in the steam outlet of the lid or under the lid in the condensation zone of boiling water vapor, and the drain of this agent is carried out under pressure through at least one radiator with a fan of an autonomous liquid cooling unit so that so that the cooled agent passing through the radiator is used for subsequent feeding under pressure into the cavity of the tube or tubes of the cover.

The method is considered on the example of a specific device for controlling the quality of crops by alpha-amylase activity.

A device for controlling the quality of grain crops by alpha-amylase activity comprises a housing with a water bath 1 located in front of the housing in the housing and with a cover 2. The water bath is a container that is sealed by a top and sealed by a lid, in the bottom of which are mounted rod heating elements 3 associated with the system their heating. An indicator (not indicated) of the water level in the bath is installed on the casing of the water bath for visual inspection. The cover 2 of the water bath contains slots for mounting the cassette 4 with tubes 5 and the rod-mixers 6 placed in them. A vapor chamber 7 is formed in the cover with an integrated water cooling loop 8 in the form of a coil. Such a coil can be mounted under a cover in the zone of phase conversion of water vapor into droplets. Above the water bath there is an indicator of visual control of the water temperature in the water bath, on which the inscription changes when the required temperature is reached.

For research or experiment, fill the water bath with distilled water through the tube opening. Check the water level in the bath by the level indicator installed on the casing of the bath, which should be in the middle of the drain pipe zone.

The tubes are washed, rinsed with distilled water, dried and installed in cassettes. A sample of ground grain or flour is placed in each tube and distilled water is poured into them at room temperature. Close the tubes with rubber stoppers and shake them until a homogeneous suspension is obtained. Tubes with a suspension (without rubber plugs) are installed in a stand with a cassette, lowered into nests made on the lid of a water bath. Test tubes with suspension are heated in a water bath, which leads to the conversion of the suspension into a paste. Then there is a capture of the rod-mixers. The design of the device provides automatic capture of the rod-mixers and their release at the command of the control unit. On command from the upper position sensor, the grippers release the stir bar, which under their own weight begin to fall down. The duration of the fall of the rod-mixers is determined by the viscosity of the paste, depending on the activity of alpha-amylase, thinning the paste. The fall of each of the rod-mixers continues until the corresponding sensor of the lower position, which stops the time counting on its channel, is triggered. The fall time of the stirrer-rod in the gelatinized water-flour suspension will be the determined fall number.

In order for water to not boil out of the water bath, the lid of the bath should be cooled. On the lid of the bath there is a steam discharge chamber 7 and a water cooling loop 8 built into it.

The device is additionally equipped with an autonomous cooling unit 9 installed in the rear part of the casing and consisting of at least one radiator 10 with at least one fan 1 1 and a non-submersible pump-pump 12 connected to the water bath cover through a water cooling loop 8 integrated in the vapor chamber 7 and circulating chilled water in a closed circuit. The built-in autonomous cooling unit includes a radiator with fans, for example, in the amount of three, and non-submersible pump pumps installed in housing 1. Water passes through a radiator cooled by high-speed fans. Standalone unit cooling is connected to the cover of the water bath through a loop 8 of water cooling, built-in in the steam cavity, which ensures the circulation of chilled water in a closed circuit.

The use of an autonomous cooling unit, feeding under

5 pressure, the cooling liquid in the vapor chamber (made in the form of a separate chamber in the lid or directly under the lid) allows water vapor to be cooled above the level of boiling water (under the lid, in the zone of natural transition of water vapor into water droplets) and to dump these droplets into boiling layer of water in the tank. With proper regulation of the degree of cooling in relation to the volume of vapors, it is possible to ensure a continuous cycle of water in the tank without the release of vapors through the steam removal system or pressure relief valve. Thus, a constant volume of water will be maintained in the capacity of the water bath at a certain constant level, which allows guaranteed washing of the tubes over the entire height of the test suspension. The use of an autonomous liquid cooling unit with circulation of a cooling agent in a closed circuit allows eliminating

20 the need for supply from outside the cooling agent. Since research or testing devices operate in stationary conditions and, as a rule, in enclosed spaces, the use of fans with radiators from one or more pieces in a unit provides cooling of the working agent in a closed loop

25 even in adverse operating conditions. The closed loop system allows you to adjust the degree of cooling of the working agent of the device in order to synchronize the process of cooling water vapor and bring it to vapor condensation directly under the cover.

Using the proposed method allows to increase the solution of the technical problem for the execution of the device water-independent and resource-saving, which allows you to save water in volumes up to 1000 liters per day on one device. It works autonomously in agricultural labs. In addition, this method can be implemented by a device made using component structural elements, the creation of which is not difficult for specialists in this field.

Claims

Claim

A method of cooling a lid of a water bath of a research or testing device, which comprises passing under pressure a stream of a cold liquid agent through a lid of a water bath of a research or testing device and draining this agent, characterized in that an autonomous liquid cooling unit is used for supplying a pressure of a stream of cold liquid agent circulation of the cooling agent in a closed circuit, and a stream of cold liquid agent is passed through a tube or tubes placed e in the vapor outlet cavity of the lid or under the lid in the condensation zone of boiling water vapor to ensure that this agent is drained under pressure through at least one radiator with a fan of an autonomous liquid cooling unit for subsequent supply of pressure of the agent cooled in the radiator into the cavity of the tube or tubes.