RU2027445C1 - Device for emanating volatile matter into air medium - Google Patents

Abstract

FIELD: medical equipment; industrial sanitary. SUBSTANCE: device has case 1 with inlet and outlet holes 3 and 4, contrivance 5 for creating air flux, heater 6, tank 8 made in form of reservoir with changeable volume, transmission mechanism 10, control unit, which has transmission mechanism control module and modules 23-25 for setting check of making of unitary dose of initial matter, period of supplying unitary doses and number of unitary doses. EFFECT: improved efficiency; improved safety. 14 cl, 1 dwg

Description

 The invention relates to medical equipment, and in particular to devices for the emission of volatile substances, for example biologically active compounds, into the air.

 A device is known for releasing volatile substances into the air, comprising a housing with a working channel between the inlet and outlet openings, in which an evaporator is arranged in the form of an odor carrier, the latter being made of a flat suction material.

 The regulation of the release of volatile substances in this embodiment of the device is due only to the properties of the used suction material and the vaporized substance; changing the evaporation mode during operation is virtually impossible.

 It is also known a device for the emission of volatile substances into the air, comprising a housing with a working channel, a device for creating an air flow, a container connected to an evaporator, a device for supplying the starting substance, and a device for changing the operating mode of the device, made in the form of series-connected power sources, an alternating current source, a frequency divider and a frequency-controlled electric motor of a device for creating an air flow.

 The disadvantage of this device is the restrictive ability to control the evaporation mode, which boils down to only changing the intensity of removal of volatile substances released into the air from the evaporator core.

 Known devices for the emission of volatile substances into the air, containing a housing with a working channel between the inlet and outlet openings and an evaporator, which provide some possibility of changing the evaporation mode either by changing the position in the space of the entire device and setting it in the active or passive position, or by changing the position of the slide gate introduced into the device’s body in combination with the reservoir and providing the possibility of changing the emission intensity of evaporated substances - m Between its minimum and maximum values - with a change in the intensity of the feed of the initial substance from the tank.

 The disadvantage of these devices is the limited resolution of the regulation of evaporation modes, manual control and subjectivity of the task and implementation of the parameters of the evaporation regimes and, therefore, the very limited ability to implement (reproduce) the evaporation regimes, in particular, substances with various properties and characteristics of exposure to biological objects.

 Known devices for the emission of volatile substances into the air, containing a housing with holes, a container and an evaporator, as well as a device for dosing a sample of the initial liquid. A feature of these devices is the pulsed mode of operation, implemented by pressing (manually) on the housing, which slightly increases the resolution, but is also characterized by very limited accuracy in the implementation of various evaporation modes.

 The closest in technical essence to the proposed device is the selected device as a prototype device for the release of volatile substances into the air, containing a housing with a working channel between the inlet and outlet openings, devices for creating an air flow in the working channel, a container, an evaporator made in the form of a rod , and a device for supplying the starting substance (liquid) to the evaporator, which is made in the form of a valve with a knife gate installed in the bottom of the tank and driven electromagnetic wave [1].

 A feature of the prototype device is the possibility of implementing a pulsed feed mode of the feed to the evaporator, which slightly increases the possibility of changing the evaporation mode (compared to the previous group of known devices).

 At the same time, the disadvantage of the prototype device is the impossibility of setting and implementing (monitoring the implementation) of quantitatively regulated parameters that determine the unit dose of supply of the starting substance in each cycle of its selection from the tank, since the device does not have the ability to measure the specified unit dose - there is no feedback loop providing measurements of the parameters of the actually implemented supply of a single dose and comparing them with the task for the controlled formation of the latter. In addition, the amount of substance in a single dose sold in the prototype device largely depends on the differences in the properties of the starting fluids used, as well as on the change in these properties over time, for example, when the temperature changes (in particular, due to the dependence of the viscosity of most liquids, especially oils, widely used in devices of this purpose).

 The purpose of the invention is to increase the resolution and accuracy of the implementation of the modes of emission of volatile substances, as well as automation of workflow management and control of the actual performance of both current and integral parameters of the feed of the starting materials (regardless of differences in the properties of these substances and while ensuring the possibility of their rapid replacement) .

 To do this, in a device for the emission of volatile substances into the air, for example biologically active compounds, evaporating from the starting material, containing a housing with a working channel between the water and outlet openings, a device for creating an air flow in the working channel, a heater, and also an evaporator and a tank , made mainly in the form of a removable module and placed with the possibility of interaction with the capacity of the device located in the housing for supplying the starting substance, the capacity is made in the form of ervuara variable object, a device for feeding a starting material - in the form of a drive connected to the control and monitoring unit.

 The reservoir of variable volume can be made in the form of a vessel in which at least part of its shell is made of elastic material, in particular in the form of a bellows.

 The reservoir of variable volume can also be made in the form of a cylinder with a piston connected to the rod.

 The drive can be made in the form of a positioner with a working body, the latter being equipped with a sensor element, in particular tactile.

 The positioner can also be made in the form of a reversible electric motor, kinematically connected through a gearbox with a converter of angular displacement to linear.

 The positioner is equipped with a measuring transducer of displacement, which can be made in the form of a pulse transducer of the angle of rotation.

 The control and monitoring unit can be made in the form of a drive control module.

 In addition, the unit for setting and monitoring the execution of a single dose, the module for setting and monitoring the execution of the period for supplying unit doses, and the module for setting and monitoring the execution of the number of unit doses can be introduced into the control and monitoring unit.

 At the same time, each task and execution control module is made in the form of a pulse counter, task element, comparator and indicator with a decoder, the pulse counter of the unit dose execution control module is in the form of a counter with a preset, and the drive control module is made in the form of on and off elements, a shaper control signals, permission elements and key. An impulse generator is additionally introduced into the unit for setting and monitoring the unit dose delivery period, and the units for setting and controlling the execution of unit doses are connected to the drive control module, and the displacement transducer is connected to the input of the pulse counter of the unit for setting and controlling the execution of unit doses through a series-connected key and element resolution of the account, the control input of which is connected to the sensor element of the working body of the positioner.

 The technical result achieved by the implementation of the present invention is that the device provides the formation of a pulsed stream of unit doses of starting materials with metrologically regulated implementation of all separately set characteristics of this stream - the values of a unit dose, the period of supply of unit doses and the number of unit doses, t. e. high resolution and accuracy of the task and control of execution are provided, both of the current parameters of the specified pulse flow corresponding to the intensity of the feed of the initial substance into the evaporator (values of unit doses and the period of their supply), and the integral parameter (number of unit doses).

 The presence of a causal relationship between the totality of the essential features of the invention and the achieved technical result is obvious (which is also confirmed by the description of an example implementation of the proposed device).

 The drawing shows a block diagram of a device.

 A device for the emission of volatile substances, for example biologically active substances, evaporating from the starting material into the air, comprises a housing 1 with a working channel 2 between the inlet 3 and the outlet 4, a device 5 for creating an air flow in the working channel 2, a heater 6, as well as an evaporator 7 and a container 8 with a dispenser, made mainly in the form of a replaceable module 9 and placed with the possibility of interaction with a container 8 with a dispenser and a transmission mechanism 10 for supplying Nogo material. A control and monitoring unit 11 is introduced into the device, the capacity 8 of the replaceable module 9 is made in the form of a variable volume tank, and the transmission mechanism 10 is made in the form of a positioner 12 with a working body 13, the latter being equipped with a tactile sensor element 14.

 The reservoir 8 of variable volume is made in the form of a cylinder 15 with a piston 16 connected to the rod 17.

 The positioner 12 is made in the form of a reversible electric motor 18, kinematically connected through a gearbox 19 with a converter 20 of angular displacement to linear.

 The positioner 12 is equipped with a measuring transducer 21 displacement, which is made in the form of a pulse transducer angle of rotation.

 The control and monitoring unit 11 is made in the form of a unit 22 for controlling the positioner 12, a unit 23 for setting and monitoring the execution of a single dose, a unit 24 for setting and monitoring the execution of the transmission period of unit doses, and a unit 25 for setting and monitoring the execution of the number of unit doses.

 Each task and execution control module (22–25) is made in the form of a pulse counter, 26–28, respectively, a task element, respectively, 29–31, a comparator, respectively, 32–34, and also an indicator with a decoder, respectively, 35–37. Moreover, the pulse counter of the module 23 of the task and control the execution of a single dose is made in the form of a counter with a preset.

 The positioner 12 control module 22 is made up of an on element 38 and an off element 39, a control signal generator 40, an account resolution element 41 and a key 42, and a pulse generator 43 is additionally introduced into the module 24 for setting and monitoring the execution of the unit dose delivery period.

 Modules 23-25 for setting and monitoring the execution, respectively, of a unit dose of the unit dose delivery period and for the number of unit doses are connected to the positioner control module 22, the displacement transducer 21 being connected to the input 44 of the pulse counter 26 of the module 23 for setting and monitoring the execution of a single dose through a series-connected key 42 and the account resolution element 41, and the control input 45 of the latter is connected to the sensor element 14 of the working body 13 of the positioner 12.

 The driver 40 of the control signals of the control module 22 is made in the form of a logical inverter 46, a trigger 47 with logic processing elements and an switching element 48.

 The device operates as follows.

 When preparing the device for operation, information corresponding to the set value of a unit dose is entered into the element 29 of the module 23 task, information corresponding to the set value of the unit dose delivery period is entered into the element 30 of module 24 task, and information corresponding to the given quantity is entered into element 31 of the module 25 task single doses.

 After installing a removable module 9 with the evaporator 7 and the variable volume reservoir 8 filled with the source substance (liquid) in the housing 1 of the cylinder 15 with the piston 16 when the trigger element 38 is affected due to a change in the state of the trigger 47 in the driver 40 of the control signals, a connection is made to the power source ( not shown) in the corresponding polarity of the reversible electric motor 18 of the positioner 12, as a result of which the working body 13 of the latter is due to the action of the angular displacement transducer 20 in a linear new - starts moving towards the rod 17 of the piston 16 of the cylinder 15. At the moment of achieving mechanical contact with the rod 17 of the tactile sensor element 14, a signal appears at the output of the latter, which is fed to the control input 45 of the account resolution element 41 and puts the latter into the connection state of the input with exit. In this case, the key 42 is in the closed state (since the signal that controls it comes from the output of the logical inverter 46, at the input of which there is no output signal from the comparator 34 of the module 25, since prior to the operation of the device, none of the unit doses from the given number were performed - by entering relevant information into the element 31 of the task module 25).

 As a result of this, the pulse output signal of the displacement transducer 21 is fed to the input 44 of the pulse counter 26, into which, as a result of a preset, a number corresponding to the volume of the cylinder 15, completely filled with the initial substance, is entered, and which starts working in the mode of counting down (subtraction).

 The current state of the pulse counter 26 is presented on the indicator 35, i.e., the readings of the latter correspond to the current value of the amount of the starting substance in the cylinder 15, and the change in the state of the pulse counter 26 is compared in the comparator 32 with the value set using the element 29, and after reaching the equality of these values a signal appears at the output of the comparator 32, the effect of which at the trigger 47 translates it into a state that causes the reverse motor 18 to turn off. This completes the formation of a single dose a corresponding amount of the starting material delivered from the cylinder 15 into the evaporator 7 evaporates.

 At the moment of operation of the count resolution element 41 and the first next pulse moving from the measuring transducer 21 to the input 44 of the counter 26, the change in the state of the switching element 48 is caused by the same pulse, as a result of which a signal is supplied to the control input of the pulse generator 43 of the task module 24 and monitoring the implementation of the unit dose delivery period. From the output of the generator 43 pulses are fed to the input of the counter 27 pulses, the latter begins to count them. Thus, the formation of a period of submission of unit doses begins.

 The current state of the counter 27 pulses is compared in the comparator 33 with the task code coming from the element 30 of the task, and is also indicated by the indicator 36, the readings of which correspond to the executed part of the period of submission of single doses.

 At the moment of completion of the formation of a predetermined period for the delivery of unit doses, the signal from the output of the comparator 33 changes the state of the trigger 47, as a result of which the reversible motor 18 is again turned on in the direction corresponding to the further displacement of the starting substance from the cylinder 15 (i.e., the formation of the next unit dose ), at the same time, the counter of 27 pulses is set to the initial state and the formation of the next period for submission of unit doses begins. In addition, the specified output signal of the comparator 33 of the module 24 is supplied to the main input of the pulse counter 28 of the module 25 for setting and monitoring the execution of the number of unit doses, i.e., the counting starts, indication (using the indicator 37) in the comparator 34 of the current quantity of the execution of unit doses.

 After execution (formation) of the number of unit doses equal to the given signal from the output of the comparator 34, acting on the logical elements of the trigger 47, the latter is transferred to a state that disables the reversible electric motor 18 and the end of the formation of both the last unit dose and the entire series of a given number of unit doses, which completes the cycle of the device.

 When replacing one type of starting material with another, the used replaceable module 9 (with the corresponding reservoir of variable volume) is removed from the device and replaced by another, and at the time of removing the replaceable module due to a change in the state of the control fixing elements (not shown), a control signal for the reversible electric motor 18 is formed, providing the return of the working body 13 of the positioner 12 to its original position (this process is implemented in a known manner and is not considered in detail).

 After installing a replaceable module in the device’s body with a reservoir containing another starting substance, and turning on the device, the next cycle of its operation is implemented (in accordance with the above description).

Claims (15)

 1. DEVICE FOR ISOLATING VIABLE MATTERS TO AIR, mainly biologically active compounds, comprising a housing with air inlet and outlet openings connected by a working channel, a device for creating an air flow, a container with a starting substance and a dispenser for the latter, a control unit, characterized in that the container with the starting material and the dispenser are made in the form of a variable volume reservoir with a transmission mechanism, while the transmission mechanism for changing the volume of the reservoir is connected to the unit a systematic way.  2. The device according to claim 1, characterized in that the reservoir of variable volume is made in the form of a vessel in which at least part of its shell is made of elastic material.  3. The device according to claims 1 and 2, characterized in that the reservoir of variable volume is made in the form of a vessel, in which at least part of its shell is made in the form of a bellows.  4. The device according to claim 1, characterized in that the reservoir of variable volume is also made in the form of a cylinder with a piston connected to the rod.  5. The device according to claim 1, characterized in that the transmission mechanism is made in the form of a positioner with a working body.  6. The device according to claim 1, characterized in that the working body of the positioner is equipped with a sensor element.  7. The device according to claims 1 and 6, characterized in that the working body of the positioner is equipped with a tactile sensor element.  8. The device according to claim 1, characterized in that the positioner is made in the form of a reversible electric motor kinematically connected through a gearbox with a converter of angular displacement into a linear one.  9. The device according to claims 1 and 8, characterized in that the positioner is equipped with a movement measuring transducer.  10. The device according to PP.1,8 and 9, characterized in that the measuring transducer displacement is made in the form of a pulse transducer angle of rotation.  11. The device according to claim 1, characterized in that the control unit is made in the form of a transmission control module.  12. The device according to PP.1 and 11, characterized in that the control unit is equipped with a task module and control the execution of a single dose.  13. The device according to claims 1 and 11, characterized in that the control unit is equipped with a task and control module for the execution of the unit dose delivery period.  14. The device according to PP.1 and 11, characterized in that the control unit is equipped with a task module and control the execution of the number of unit doses.  15. The device according to claims 1.11 to 14, characterized in that each of the task and execution control modules is made in the form of a pulse counter, task element, comparator and indicator with a decoder, the pulse counter of the task and control unit of the unit dose execution is made in the form a counter with a preset, the drive control module is made in the form of on and off elements, a control signal shaper, counting and key resolution elements, a generator is additionally introduced into the module for maintaining and monitoring the period for supplying unit doses pulses, and the modules for setting and controlling the execution of unit doses, the period for delivering unit doses and the number of unit doses are connected to the drive control module, and the displacement transducer is connected to the input of the pulse counter of the unit for setting and monitoring the execution of unit doses through a series-connected key and an element of account resolution, the control input of which is connected to the sensor element of the working body of the positioner.