RU2131307C1 - Method and device for applying substances onto surface to be treated - Google Patents

Abstract

FIELD: materials treatment. SUBSTANCE: preliminarily, substance is placed into container interconnected with coating-application device to enable dosed delivery of substance to be applied. Minimum dose value V₁ and its maximum value V₂ delivered in unit time are chosen within the limits 0.18 ≤(V₁+αV₂)≤ 4.6 where α is experimental coefficient depending on viscosity, porosity, and flowability of substance within the limits 0.18 ≤α≤ 3.6. Device-mediated extraction of volumes and their displacement on their application area is performed using energy doses E₁ which are interrelated with total energy dose E₂ consumed for displacement of device relative to surface being treated and/or applying substances, or with energy capacity E₂ of autonomous power sources by the following inequality: 1 ≤(βE₁+E₂)/E₂≤ 6.1 wherein β is experimental coefficient depending on plasticity and adhesive characteristics of substance within a range of 0.27 ≤β≤ 5.3. Device is interconnected with additional volume of substance to be applied and with mechanisms for dosed delivery of that substance and its displacement to desired surface region. Value V₃ of volume of substance to be applied is interrelated with total volume V₄ occupied by device by the following inequality: 1.01 ≤(γV₃+V₄)/V₄≤ 2.3 wherein γ is experimental coefficient depending on porosity of substance and productivity of device within the limits 0.65 ≤γ≤ 1.5. Constructional features of dosed delivery mechanism are determined by value of volume of substance being delivered in unit time within the limits 1.00006 ≤(λV₅+V₃)/V₃≤ 3.8 where λ is experimental coefficient depending on porosity, hardness, and flowability of substance within a range of 0.14 ≤λ≤ 2.8. Ratio of minimum cross-section of device L₁ to its maximum dimension L₂ is chosen within the limits 0.74 ≤(L₁+δL₂)/L₂≤ 3.3 where δ experimental coefficient depending on configuration of device and ergonomic requirements of potential consumer ranging from 0.68 to 2.3. EFFECT: improved consumer's characteristics of device. 2 cl, 1 dwg

Description

 The invention relates to the field of consumer goods and can be used, for example, for the manufacture of a device for applying substances, for example, dyeing or cleaning various materials to the surface.

 A known method of applying substances to the treated surface, including the supply of substances to the application area and coating them with the treated surface [Auth. testimonial. USSR N 755319, IPC B 05 C 1/06, 08/15/1980].

 A device for applying substances to the surface of materials, containing means of accumulation and subsequent application of substances to the surface of materials [Auth. testimonial. USSR N 755319, IPC B 05 C 1/06, 08/15/1980].

 A known method of applying substances to the treated surface, including preparing the applied substance, feeding it into the application area and coating it with the treated surface [RF Patent N 2088345, IPC B 05 C 1/06, 08/27/1997,] - prototype.

 There is also known a device for implementing a method of applying substances to a surface to be treated, comprising a body, a substance to be applied and mechanisms for applying the substance and distributing it over the surface to be treated [RF Patent N 2088345, IPC B 05 C 1/06, 08/27/1997], a prototype .

 A disadvantage of the known methods and devices is their relatively low productivity of deposition of substances on the treated surface, due to the disadvantages of the methods of their manufacture, interrelated with the structural disadvantages of the devices.

 The technical problem to be solved in accordance with the invention is to improve the consumer properties of the method and device with achieving a technical result with respect to increasing productivity and uniformity of the application of substances on the treated surface while increasing the efficiency of application.

As brief information revealing the essence of the invention, it should be noted that the achieved technical result is achieved using the proposed method of applying substances to the surface to be treated, including preparing the substance to be applied, feeding it into the application area and coating it with the treated surface. Distinctive features of the method are that in the process of preparing the applied substance, it is placed in the volume of its content, interconnected with the device for applying substances, with the possibility of dosed extraction from the volume of applied substances. The minimum value of V ₁ and the maximum value of V ₂ doses of substances extracted per unit time are chosen in the range 0.18 ≤ (V ₁ + α V ₂ ) / V ₂ ≤ 4.6 where α is the experimental coefficient chosen depending on the viscosity , porosity and fluidity of the applied substance in the range of 0.18 ≤ α ≤ 3.6.

The extraction of volumes and movement in the area of their application by the device onto the surface to be treated is performed using doses of energy E ₁ that are selected from the total energy E ₂ spent on moving the device relative to the surface to be treated and / or applying substances, or from the energy content E _{2 of} autonomous energy sources within 1 ≤ (β E ₁ + E ₂ ) / E ₂ ≤ 6.1, where β is the experimental coefficient selected depending on the ductility and adhesive characteristics of the applied substance within 0.27 ≤ β ≤ 5.3.

As brief information disclosing the essence of the invention, it should be noted that the achieved technical result is provided using the proposed device for implementing the method of applying substances to the treated surface, comprising a housing, a deposited substance and mechanisms for applying the substance and its distribution over the treated surface. Distinctive features of the device are that it is interconnected with an additional volume of the applied substance content and with the mechanisms of metered extraction (MDI) of the applied substance from the volume and its movement to the application area on the surface to be treated. The value of V _{3 the} volume of the content of the applied substance is selected in relation to the entire volume V ₄ occupied by the device, within 1.01 ≤ (γ V ₃ + V ₄ ) / V ₄ ≤ 2.3, where γ is the experimental coefficient, selected depending from the porosity of the applied substance and the performance of the device in the range of 0.65 ≤ γ ≤ 1.5.

The structural features of MDI are determined by the volume V ₅ of the MDI recovery of the applied substance per unit time within 1.00006 ≤ (λ V ₅ + V ₃ ) / V ₃ ≤ 3.8, where λ is the experimental coefficient selected depending on porosity and rigidity and the fluidity of the applied substance in the range of 0.14 ≤ λ ≤ 2.8, and the ratio of the minimum size L _{1 of the} cross-section of the device and its maximum size L _{2 is} selected in the range of 0.74 ≤ (L ₁ + δ L ₂ ) / L ₂ ≤ 3.3, where δ is the experimental coefficient selected depending on the configuration of the device and ergonomic Required for the potential consumer within 0,68 ≤ δ ≤ 2,3.

 It is advisable to explain the proposed device with a drawing, which schematically shows an embodiment of the proposed device in the form of a cross section of the device passing through its geometric center, where 1 is the body, 2 is the plate, 3 is the carrier, 4 is the axis of rotation of the plate relative to the body, 5 - thrust stand with a channel for removal of applied, for example, cleaning agent, 6 - housing of the bottle with cleaning agent, 7 - feed axis with thread, 8 - piston, 9 - applied, for example, cleaning agent, 10 - support legs of the drive and the feed axis, 11 - the ratchet drive of the feed axis, 12 - the ratchet axis, 13 - the step regulator of the amount of supply of the cleaning substance, 14 - the rack of the regulator of the quantity of supply of the cleaning substance, 15 - the ratchet drive tooth, 16 - the return spring, 17 - the limiter in the form protrusions, 18 - a channel for supplying a cleaning substance to the cleaning zone.

 With a detailed description of the method, it is impractical to dwell in detail on the features known from published data on the performance of its operations, in particular on the known features of the preparation of the applied substance, its supply to the area of application and coating of the treated surface. In detail, it is advisable to dwell only on the distinguishing essential structural features of the proposed method, namely, that in the process of preparing the applied substance, it is placed in the volume of its content, interconnected with the device for applying substances, with the possibility of dosed extraction from the volume of applied substances. The amount of applied substances can be either closed or non-closed, and the extraction of substances from it can be, for example, by squeezing them out of the volume or flowing out under the action of gravity.

The minimum value of V ₁ and the maximum value of V ₂ doses of substances extracted per unit time are selected in the range of 0.18 ≤ (V ₁ + α V ₂ ) / V ₂ ≤ 4.6, where α is the experimental coefficient, chosen depending on viscosity, porosity and fluidity of the applied substance in the range of 0.18 ≤ α ≤ 3.6. The indicated range of recoverable doses of substances covers almost all necessary practical cases. Extraction of volumes of substances and movement in the area of their application by the device onto the surface to be treated is performed using doses of energy E ₁ that are from the total energy E ₂ spent on moving the device relative to the surface to be treated and / or applying substances, or from the energy content E _{2 of} autonomous energy sources selected within 1 ≤ (β E ₁ + E ₂ ) / E ₂ ≤ 6.1, where β is the experimental coefficient selected depending on the ductility and adhesive characteristics of the applied substance within 0.27 ≤ β ≤ 5.3. Among the autonomous energy sources can be, in particular, cylinders with compressed gas or gravitational energy of the gravitational field.

With a detailed description of the device, it is not advisable to dwell in detail on the known structural features known from the published data, in particular on the known features of the housing, the applied substance and the mechanisms for applying the substance and its distribution over the treated surface. In detail, it is advisable to dwell only on the distinctive essential structural features of the proposed device, which consists in the fact that it is interconnected with the additional volume of the applied substance content and with the mechanisms of metered extraction (MDI) of the applied substance from the volume and its movement to the area of its application onto the surface to be treated. Structurally, the volume of the content of the applied substance and the MDI of the applied substance from the volume and moving to the area of its application onto the surface to be treated can be placed both inside the housing of the substance distribution mechanism on the treated surface and outside this body. The value V _{3 of the} volume of the applied substance content is selected with respect to the entire volume V ₄ occupied by the device, within 1.01 ≤ (γ V ₃ + V ₄ ) / V ₄ ≤ 2.3, where γ is the experimental coefficient, selected as a function of from the porosity of the applied substance and the performance of the device in the range of 0.65 ≤ γ ≤ 1.5. Structurally, the amount of applied substances can be made, for example, in the form of a cylinder, cone, ellipsoid, tray, etc.

The structural features of MDI are determined by the volume V ₅ of the MDI recovery of the applied substance per unit time within 1.00006 ≤ (λ V ₅ + V ₃ ) / V ₃ ≤ 3.8, where λ is the experimental coefficient selected depending on porosity and rigidity and the fluidity of the applied substance in the range of 0.14 ≤ λ ≤ 2.8, and the ratio of the minimum size L _{1 of the} cross-section of the device and its maximum size L _{2 is} selected in the range of 0.74 ≤ (L ₁ + δ L ₂ ) / L ₂ ≤ 3.3, where δ is the experimental coefficient selected depending on the configuration of the device and ergonomic t requirements of the potential consumer within 0.68 ≤ δ ≤ 2.3. Other design features of MDI are not essential for achieving a technical result, except for those that are structurally predetermined by the above attribute. The ratio of sizes L ₁ and L ₂ within the specified limits covers the necessary practical options for implementing the proposed device.

 It is advisable to describe in detail the following one of the options for the practical implementation of the proposed device, called "Dividic-automatic" (see drawing). "Dividic-automatic" consists of a housing 1, a plate 2 with a carrier of substance 3. The plate is connected to the housing by an axis 4. The movement of the plate relative to the axis clockwise is limited by the protrusion 17 of the housing, and counterclockwise by the stop of the rack 14 in the housing 1 The distance to the stop in the housing can be changed using the engine 13 to ensure a change in the angle of rotation of the plate 2 relative to the axis 4. On the plate 2 there are racks 10, between which there is a ratchet 11, made integral with the axis 12. The axis 12 is made to rotate Iya in the holes of the racks. The drive tooth 15 of the ratchet is fixedly mounted on the plate 2.

 Structurally, "Dividic-automatic" is made of the following main components: a housing, a cleaning agent carrier with channels for supplying the substance to the cleaning zone, a drive of the feeding mechanism, an thrust stand with a channel for cleaning the substance, a device for the step-by-step regulator of supplying the quantity of cleaning substance, a replacement cylinder with a cleaning substance and its feed mechanism.

 The housing 1 is the supporting structure of the entire product. It contains the carrier 3 of the substance, made, for example, in the form of a brush and mounted on the plate 2, as well as the channel 18 for supplying the cleaning substance to the cleaning zone, which is a system of flexible pipelines passing through the holes in the plate 2. A leading tooth is also installed on the plate 2 15 ratchet 11 and rack 14 of the regulator of the amount of supply of cleaning substance. The plate 2 is connected to the housing 1 by an axis 4. The movement of the plate clockwise is limited by the protrusion 17. The movement of the plate 2 relative to the axis 4 counterclockwise is determined by the gap between the housing 1 and the rack 14 of the regulator of the amount of supply of cleaning substance. The size of the gap depends on the position of the step regulator 13 of the supply quantity of the cleaning substance.

 The drive of the feed mechanism is made of support columns 10 and ratchet 11, made at the same time with the axis 12. The end face of the axis 12 is provided with a groove for engaging and transmitting rotation to the feeding axis 7.

 The thrust stand 5 is provided with a channel for removal of the cleaning substance. The outlet of this rack is connected to the channels 18 for supplying the cleaning substance to the cleaning zone.

 The device of the stepwise regulator of the supply quantity of the cleaning substance is made in the form of an engine 13 with the possibility of its movement in the groove of the housing 1. The stepwise cut-out of the engine changes the stroke of the rack 14 of the controller and, accordingly, the angle of rotation of the ratchet 11 for one cycle multiple of the number of teeth.

 The replacement cylinder 6 is filled with a cleaning agent 9. The left end of the cylinder 6 has an outlet that is aligned with the receiving hole of the thrust post 5. The right end of the cylinder in its initial position is closed by a piston 8. A feed axis 7 with a thread is placed along the entire length of the cylinder 6. The axis 7 passes through a threaded hole in the center of the piston 8. The protruding part of the axis 7 has a shaped groove, which, when a cylinder 6 is inserted between the support post 10 and the support post 5, engages with a groove in the axis 12 of the ratchet 11.

 The operation of the device is as follows. When applying, for example, a cleaning agent to the material surface to be treated, a vertical component of the force is applied, applied through the carrier 3 to the plate 2. When the plate 2 is moved relative to the housing 1, the leading tooth 15 of the ratchet 11 rotates it by a certain angle. The rotation of the ratchet 11 is transmitted to the feed axis 7. Rotating, the axis 7 moves the piston 8, which squeezes the cleaning substance 9 from the cylinder 6 through the channels for supplying the cleaning substance to the cleaning zone, which is then distributed over the surface of the processed material. The process is repeated periodically during cleaning, providing a metered supply of the substance. Can be implemented and other options for devices for implementing the proposed method. For example, the cylinder may be located on the plate with the corresponding transfer of the remaining elements.

 On the surface of the housing, protrusions and grooves or grooves can be made, which are used, in particular, for fastening parts and details of the device, decorative, informational and identification images, as stiffeners to prevent the device from slipping out of hands, etc. In this case, a geometric structure is formed individual nodes of the device, reaching the maximum value of manufacturing accuracy, in particular the distances between the most distant points in the manufactured nodes.

 The set of essential features of the claimed object, as follows from the foregoing, also covers embodiments of the device with removable volumes of the applied substance or carriers with both one type of applied substance and several. In this case, interchangeable holders and carriers can be specialized, for example, according to the type of substance applied.

 The technical result achieved, as shown by the experimental data, can only be realized by an interconnected set of all the essential features of the claimed objects reflected in the claims. The differences indicated in it give reason to conclude that the technical solution is new, and the totality of the claimed claims in connection with their non-obviousness is about its inventive step, which is also proved by the above detailed description of the claimed objects. Compliance with the criterion of "industrial applicability" of the declared objects is proved both by the wide receipt and use of various methods and devices for applying substances to materials on an industrial scale, and by the absence of any practically difficult features in the claimed claims. The lower and upper values of the declared limits were obtained on the basis of statistical processing of the results of experimental studies, analysis and generalization of them and known from published data sources using the results of inventive intuition, based on the conditions for achieving the specified technical result.

 To assess the achieved technical result, we selected, for example, a parameter that determines the ratio of the uniformity of the deposition of substances on materials, and a parameter that determines the ratio of the efficiencies (amounts of substance per unit area) of the deposition of substances on the surface of the materials when using the proposed method and prototype under adequate conditions. As experiments showed, in the described embodiment of the device, the value of these parameters was achieved one and a half to two times higher than that of known objects of a similar purpose.

 In addition to the technical result indicated above, the practical implementation allows to significantly expand the possibilities of using the claimed technical solution as applied, for example, to various types of surfaces and materials applied to them, increase the safety of use and significantly enhance the consumer effect of using the Dividic-Automatic device. The claimed device is economical in applying substances to materials, has high environmental, ergonomic and other high-quality consumer properties.

Claims (2)

1. The method of applying substances to the treated surface, including preparing the applied substance, feeding it into the application area and coating it with the treated surface, characterized in that during the preparation the applied substance is placed in the volume of its content, interconnected with the device for applying substances, with the possibility of dosed extraction from the volume of applied substances, the minimum value of V ₁ and the maximum value of V _{2 the} doses of which are extracted per unit time are selected in the range 0.18 ≤ (V ₁ + α V ₂ ) / V ₂ ≤ 4.6, where α is the experiment the net coefficient, selected depending on the viscosity, porosity and fluidity of the applied substance in the range of 0.18 ≤ α ≤ 3.6, the extraction of volumes and moving in the area of their application by the device on the treated surface is carried out using doses of energy E ₁ that are from the total value energy E ₂ spent on moving the device relative to the surface to be treated and / or applying substances, or on the energy content E _{2 of} autonomous energy sources are selected in the range 1 ≤ (β E ₁ + E ₂ ) / E ₂ ≤ 6.1, where β - experimental to coefficient selected according to the ductility and adhesion characteristics of the applied substance within 0,27 ≤ β ≤ 5,3. 2. A device for implementing a method of applying substances to a surface to be treated, comprising a body, a substance to be applied, and mechanisms for applying the substance and distributing it over the surface to be treated, characterized in that it is interconnected with the additional volume of the applied substance and the dosed extraction (MDI) mechanisms of the substance applied volume and movement in the area of applying it to the surface to be treated, the value of V _{3 the} volume of the content of the applied substance is selected in relation to the entire volume of V ₄ occupied by the device, in the range of 1.01 ≤ (γ V ₃ + V ₄ ) / V ₄ ≤ 2.3, where γ is the experimental coefficient selected depending on the porosity of the applied substance and the performance of the device in the range of 0.65 ≤ γ ≤ 1.5, the design features of MDI are determined by the volume of MDI extraction of the applied substance per unit time within 1.00006 ≤ (λ V ₅ + V ₃ ) / V ₃ ≤ 3.8, where λ is the experimental coefficient selected depending on the porosity , rigidity and fluidity caused substance within 0,14 ≤ λ ≤ 2,8, and the ratio of the minimum size of L ₁ n pepper device section and its maximum size L ₂ is selected in the range 0.74 ≤ (L ₁ + δ L ₂₎ / L ₂ ≤ 3,3, where δ - experimental factor selected depending on the device configuration and ergonomic requirements of potential consumers in within 0.68 ≤ δ ≤ 2.3.