JP4966566B2 - Water-based ink component adjustment device - Google Patents

Description

  The present invention relates to a component adjusting device for keeping the component ratio of a water-based ink used for gravure printing or the like at the time of printing work in the vicinity of a predetermined setting state.

  The main components of a general printing ink include a colorant such as a pigment, a binder such as a synthetic resin, and a volatile component. This volatile component is removed in the printing drying process.

  Conventionally, inks using an organic solvent as a volatile component have been widely used. Recently, however, water-based inks containing water as a main component instead of an organic solvent have been widely used in consideration of the environment.

  The volatile component of water-based ink used for gravure printing is ideally completely water-based, but an alcohol aqueous solution is usually used in consideration of wettability to a plastic film, drying properties, printing effect, and the like.

  When printing using a water-based ink containing such an alcohol aqueous solution, a volatile component in the ink evaporates during printing, and the ink component ratio changes. In particular, there is a problem in that the balance of the ink component ratio is lost due to the difference in evaporation rate between alcohol and water, which are volatile components. Therefore, in order to obtain a stable printing effect over a long period of time, it is necessary to appropriately adjust the components and always keep it in the vicinity of a predetermined setting state (for example, an initial state or a preset adjustment target state). . This is because when the ratio of volatile components, particularly alcohol components, decreases, the wettability to the plastic film decreases and the drying speed decreases.

For example, Patent Document 1 discloses a solution in which the alcohol concentration is kept constant by keeping the conductivity and viscosity of water-based ink constant.
JP 2003-191440 A

  However, in the above-mentioned Patent Document 1, when the electrical conductivity changes, an “always appropriate amount of alcohol and water is always added” so as to keep it in the initial state, and at the same time, “the added amount of alcohol and water has a constant viscosity. Is added to the addition amount data so that it is kept at the same level ", and how to add" appropriate amount "of alcohol or water to keep both conductivity and viscosity constant. There is no disclosure at all.

  It is actually not easy to add an appropriate amount of alcohol or water. If the evaporation ratio of alcohol to water is constant, an appropriate amount can be added relatively easily by adding an alcohol aqueous solution having a predetermined concentration corresponding to the ratio. However, in practice, the evaporation ratio is not always constant and varies depending on the situation. Therefore, it is difficult to add an appropriate amount by a method in which the concentration of the aqueous alcohol solution to be added is determined in advance.

  Thus, although it is one idea to add appropriate amounts of alcohol and water separately, this method is not easy because both alcohol and water affect both conductivity and viscosity. For example, even if alcohol is added first to adjust the conductivity to the set state and then water is added to adjust the viscosity to the set state, the conductivity previously adjusted changes depending on the water added later. End up. The same is true if the order is reversed.

  In view of such circumstances, an object of the present invention is to provide a water-based ink component adjusting device capable of easily and appropriately adjusting the component ratio of a water-based ink containing an aqueous alcohol solution in the vicinity of a predetermined set state.

The invention according to claim 1 for solving the above-mentioned problem is a component adjusting device for keeping the component ratio of a water-based ink containing an aqueous alcohol solution in the vicinity of a predetermined set state, wherein the ink of the water-based ink to be adjusted First physical quantity measuring means for measuring the electrical conductivity of the water-based ink, and the amount of alcohol evaporated from the ink of the water-based ink to be adjusted As the second physical quantity that changes according to the amount of water evaporation, the second physical quantity measuring means for measuring the viscosity of the water-based ink, and the water-based ink to be adjusted based on the first physical quantity and the change quantity of the second physical quantity with respect to the set state. A calculating means for calculating the evaporation amount of alcohol and water, and adding an amount of alcohol and water equal to each evaporation amount to the water-based ink to be adjusted. And means, the adding means includes a high-concentration tank for reserving a relatively high concentration of alcohol solution, and a low concentration tank for reserving the low concentration alcohol solution or water than alcohol aqueous solution of the high concentration in the tank Including adding an alcohol aqueous solution from the high-concentration tank and an alcohol aqueous solution from the low-concentration tank in an appropriate ratio, thereby adding an amount of alcohol and water equal to each evaporation amount, and calculating The means includes a first equation in which the first change amount uniquely obtained from the change from the set state of the first physical quantity is expressed using a water evaporation amount and an alcohol evaporation amount as variables, and the second physical quantity described above. The second change that is uniquely determined from the change from the set state is a simultaneous equation of the second equation that represents the amount of water evaporation and the amount of alcohol evaporation as variables. By a predetermined arithmetic expression on the principle to seek, corresponds to the alcohol and water in an amount equal to the respective evaporation, independently and addition amount of the addition amount and the low-concentration tank from the high concentration tank It is characterized by being calculated .

  In claim 1, when measuring the first physical quantity and the second physical quantity, their physical properties may be directly measured, or they may be indirectly measured by measuring their substitute characteristics.

Further, in claim 1, the alcohol aqueous solution added to the water-based ink may be an alcohol aqueous solution having an appropriate concentration. However, when an alcohol having a concentration of 100% is added to the ink, gelation may occur due to a shock. It is desirable to add as the following aqueous solution.

In addition, in claim 1, the appropriate ratio includes a case where one addition amount is zero. That is, it includes a case where the addition is performed only from the high concentration tank or only from the low concentration tank.

  The invention according to claim 2 is the water-based ink component adjustment apparatus according to claim 1, wherein the first change amount and the second change amount are respectively determined from the set state by an arbitrary amount of alcohol and an arbitrary amount of water. When the water-based ink at the evaporation point is diluted with a diluent comprising an alcohol aqueous solution having a predetermined concentration, it is proportional to the cut rate of dilution, and the proportionality constant is a linear function of the alcohol concentration of the diluent. It is characterized by that.

  The cut rate is a value indicating the degree of dilution when the undiluted ink is diluted, and is represented by (cut rate) = (diluent mass) / (undiluted ink mass). It is.

  According to a third aspect of the present invention, in the water-based ink component adjusting apparatus according to the second aspect, the first change amount and the second change amount are such that the gradients of the linear functions are positive and negative gradients. It is characterized by that.

According to a fourth aspect of the present invention, in the water-based ink component adjusting apparatus according to the third aspect, the calculating means includes the first change amount and the second change amount when a predetermined amount of the alcohol aqueous solution is added from the high concentration tank. A plurality of constants specific to the water-based ink are obtained based on the amount and the first change amount and the second change amount when a predetermined amount of the alcohol aqueous solution or water is added from the low-concentration tank. The addition amount from the high-concentration tank and the addition amount from the low-concentration tank are respectively calculated by an arithmetic expression using.

The invention according to claim 5 is the water-based ink component adjusting device according to any one of claims 1 to 4, wherein the second physical quantity measuring means is a diaphragm pump for circulating the water-based ink to be adjusted; And pulsation number measuring means for measuring the pulsation number of the diaphragm pump.

  The number of pulsations refers to the number of pulsations per unit time (for example, 1 minute).

  According to the first aspect of the present invention, as described below, the component ratio of the water-based ink containing the alcohol aqueous solution can be adjusted easily and appropriately in the vicinity of the predetermined set state.

  According to the configuration of the present invention, the first physical quantity and the second physical quantity are measured, the alcohol evaporation amount and the water evaporation amount are calculated from the change amount with respect to the set state, and the amount of alcohol and water equal to each evaporation amount is calculated. Are added to the water-based ink to be adjusted. Therefore, the ratio of alcohol and water in the water-based ink can be easily set to the state before evaporation, that is, the set state.

Each addition from the high-concentration tank and the low-concentration tank is carried out separately (after one addition is completed, the other addition is started), but almost simultaneously (both additions are started simultaneously, or at least one addition is completed) The addition of the other may be started). This is because the addition of one does not affect the determination of the addition amount of the other.

  However, it is preferable to add them almost at the same time because the temporal unevenness of the ink component ratio can be suppressed. Furthermore, when adding substantially simultaneously while making it flow, a spatial nonuniformity can also be suppressed.

  According to the first aspect of the present invention, the first change amount and the second change amount that are uniquely obtained from the change in the first physical quantity and the second physical quantity are substituted into the first equation and the second equation, and The alcohol evaporation amount and the water evaporation amount can be easily obtained by solving the simultaneous equations. In addition, since two different simultaneous equations are established for the two unknowns, the amount of alcohol evaporation and the amount of water evaporation, a unique solution can be obtained except for special cases. Therefore, the evaporation amount of alcohol and water can be obtained with high accuracy.

In particular, according to the invention of claim 1, by adding an appropriate amount of alcohol aqueous solution from each of the high concentration tank and the low concentration tank, as a result, an alcohol aqueous solution having an arbitrary concentration in the range between the alcohol concentrations of each tank is obtained. Any amount can be added (the highest concentration is added only from the high concentration tank, the lowest concentration is added only from the low concentration tank). That is, the necessary amount of water and alcohol can be easily added while preventing the ink from being affected by alteration or the like.

Moreover, the concentration of the alcohol aqueous solution in each tank is unknown by transforming the first equation and the second equation described above into variables in which the evaporation amount of the high concentration alcohol aqueous solution and the evaporation amount of the low concentration alcohol aqueous solution are variables. Or even if it is a case where it changes arbitrarily by evaporation, each evaporation amount (addition amount) is computable.

  According to the invention of claim 2, since the first equation and the second equation can be expressed by a simple binary linear equation, the arithmetic means can solve the simultaneous equations by simple arithmetic processing, and alcohol can be easily used. And the amount of water evaporation can be determined.

  According to the invention of claim 3, by making the gradient of the linear function positive and negative and negative gradient in this way, the straight line of the first equation and the straight line of the second equation become nearly parallel when graphed. It is unlikely to occur and the accuracy of the equation solution can be improved in practical terms.

According to the invention of claim 4, it is possible to calculate the required amount of alcohol and water added more easily.

According to the invention of claim 5 , a simple and low-cost apparatus can be obtained by using a diaphragm pump for circulating water-based ink also for viscosity measurement. Since there is a specific correlation between the viscosity of the ink and the pulsation number of the diaphragm pump, the characteristic is examined in advance and stored in the second physical quantity measurement unit, so that the unit of the diaphragm pump can be measured by the pulsation number measurement unit. By simply measuring the number of pulsations per hour, the viscosity of the ink can be easily measured.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a schematic configuration diagram of a water-based ink component adjusting apparatus according to an embodiment of the present invention. An ink tank 6 for storing aqueous ink containing an aqueous alcohol solution (hereinafter also simply referred to as ink) is a part of a printing machine (not shown). This printing machine is configured so that ink stored in the ink tank 6 is supplied to a printing unit (not shown) little by little as appropriate and printed.

  The water-based ink component adjusting apparatus shown in FIG. 1 is an apparatus that can perform ink component adjustment appropriately even in the printing operation of the printing press. The ink tank 6 and the suction port of the diaphragm pump 1 for circulating the ink are connected via suction hoses 7 and 8. A measurement chamber 2 for measuring the conductivity (first physical quantity) of the ink and the discharge port of the diaphragm pump 1 are connected via a discharge hose 9. The measurement chamber 2 and the ink tank 6 are connected via the discharge hoses 10 and 11. A switching valve 5 is provided at a connection portion between the discharge hose 10 and the discharge hose 11. Further, a connection portion between the suction hose 7 and the suction hose 8 and the switching valve 5 are connected via a closed circuit hose 12.

  The switching valve 5 can be switched between a state in which the discharge hose 10 and the discharge hose 11 are in communication and a state in which the discharge hose 10 and the closed circuit hose 12 are in communication. Therefore, when the switching valve 5 is switched in the direction in which the discharge hose 10 and the discharge hose 11 are communicated, the diaphragm pump 1 → discharge hose 9 → measurement chamber 2 → discharge hose 10 → switch valve 5 → discharge hose 11 → ink. An open circuit 31 of tank 6 → suction hose 7, 8 → diaphragm pump 1 is formed. On the other hand, when the switching valve 5 is switched in a direction that allows the discharge hose 10 and the closed circuit hose 12 to communicate with each other, the diaphragm pump 1 → the discharge hose 9 → the measurement chamber 2 → the discharge hose 10 → the switching valve 5 → the closed circuit hose 12. A closed circuit 32 is formed as a suction hose 8 → a diaphragm pump 1. The closed circuit 32 is a circuit that separates a small volume of ink from the ink tank 6 and circulates around the measurement chamber 2.

A high-concentration tank 15 and a low-concentration tank 16 are connected to the suction hose 8 via an electromagnetic valve, a check valve, etc., not shown. In the high concentration tank 15, a relatively high concentration (concentration n ₁ ) alcohol aqueous solution is stored. In the low concentration tank 16, an alcohol aqueous solution having a concentration lower than the concentration n ₁ (concentration n ₂ ) is stored. The density n ₁ and the density n ₂ are set to satisfy 0% ≦ n ₂ <n ₁ ≦ 90%. Each of the tanks 15 and 16 is configured to add an alcohol aqueous solution in an amount corresponding to the valve opening time to the ink in the suction hose 8 by opening the electromagnetic valve.

  Since the diaphragm pump 1 is a well-known device, its detailed structure is omitted, but it is a pump that circulates ink by pulsating the diaphragm using air (compressed air) as a power source. A pressure sensor 17 is provided in a place (for example, an air chamber not shown) where there is a large pressure fluctuation accompanying the pulsation of the diaphragm pump 1. The pressure sensor 17 detects pulsation of the diaphragm pump 1 by detecting pressure fluctuation. Specifically, the pressure sensor 17 is provided with a pulse generating means (not shown), which generates a pulse signal each time the diaphragm pump 1 pulsates.

  The measurement chamber 2 is provided with a temperature sensor 19 for measuring the temperature of the circulating ink and a temperature controller 3 for adjusting the temperature. The measurement chamber 2 is provided with a conductivity sensor 18 for measuring the conductivity of the ink.

  A calculation control unit 4 (calculation means) is provided at an appropriate position of the component adjustment device. The arithmetic control unit 4 comprises an electric circuit including a microprocessor (CPU), receives input signals including signals from the pressure sensor 17, the conductivity sensor 18 and the temperature sensor 19, and switches the switching valve 5 and the temperature regulator 3. In addition to controlling the operation, predetermined calculation processing is performed to control the opening and closing of solenoid valves provided in the high concentration tank 15 and the low concentration tank 16.

  Specifically, the arithmetic control unit 4 switches the switching valve 5 between the open circuit 31 side and the closed circuit 32 side as necessary during the operation of the diaphragm pump 1 and circulates ink in the switched circuit. Further, when the switching valve 5 is switched to the closed circuit 32 side, the arithmetic control unit 4 feedback-controls the temperature regulator 3 based on the detection signal from the temperature sensor 19 to control the temperature of the ink flowing through the closed circuit 32. Maintain a predetermined constant temperature.

  The arithmetic control unit 4 calculates the ink viscosity (second physical quantity) as follows. The pulse signal generated by the pressure sensor 17 (one pulse per pulsation of the diaphragm pump 1) is input to the arithmetic control unit 4. The arithmetic control unit 4 measures the number of pulsations per unit time (for example, 1 minute), that is, the number of pulsations, by measuring the time interval of the pulses with the clock function of the CPU. The number of pulsations generally increases as the viscosity of the ink is lower. The calculation control unit 4 stores in advance the relationship between the viscosity of the ink and the number of pulsations (conversion formula or map for conversion), and the viscosity can be obtained based on the measured number of pulsations. As described above, the diaphragm pump 1, the pressure sensor 17, and the calculation control unit 4 constitute a second physical quantity measuring unit that measures the viscosity as the second physical quantity.

  Further, the arithmetic control unit 4 determines the flow rate per unit time of the ink circulating in the open circuit 31 or the closed circuit 32 based on the pulsation number of the diaphragm pump 1 (hereinafter simply referred to as the flow rate, the flow rate per unit time). ). As the number of pulsations of the diaphragm pump 1 increases, the flow rate increases. The calculation control unit 4 stores in advance the relationship between the ink flow rate and the number of pulsations (such as a conversion formula or a map for conversion), and the flow rate can be obtained based on the measured number of pulsations.

  Further, the calculation control unit 4 is based on a change in the conductivity (first physical quantity) and viscosity (second physical quantity) of the ink in a predetermined setting state (for example, an initial state of printing or a preset adjustment target state). The respective evaporation amounts of alcohol and water are calculated (details of the calculation method will be described later). Then, the open / close valves of the tanks 15 and 16 are opened so that the alcohol aqueous solution corresponding to the amount equal to the evaporation amount is simultaneously added to the ink in the suction hose 8 from the high concentration tank 15 and the low concentration tank 16. Let

  Next, the principle of the water evaporation amount and alcohol evaporation amount calculation method performed by the arithmetic control unit 4 will be described.

  2A and 2B are diagrams showing the dilution characteristics of the ink. FIG. 2A shows the relationship between the degree of dilution (cut rate B) and the conductivity C, and FIG. 2B shows the diluent (alcohol aqueous solution) in the characteristics shown in FIG. The relationship between the alcohol concentration N and the characteristic gradient α is shown.

FIG. 2A shows the ink cut rate B as the degree of dilution on the horizontal axis. The cut rate B is a value represented by B = (mass of diluent) / (mass of undiluted ink). Cut rate of cut rate B ₁ represents the set point (set state), cut rate B ₀ is the cut rate of the vaporization point. The evaporation point is the state of the ink after an arbitrary amount of alcohol and water has evaporated from the ink at the set point. The vertical axis of FIG. 2A shows the reciprocal of the conductivity C, that is, 1 / (conductivity C). Conductivity C ₁ is the set point conductivity and conductivity C ₀ is the evaporation point conductivity.

Therefore, the characteristics shown in FIG. 2A are based on the evaporation point (B ₀ , 1 / C ₀ ), and the cut rate B and 1 / (conductivity when the diluent is added to the ink at the evaporation point. It represents the relationship with the rate C). The characteristic T ₁ indicated by the solid line passes through the set point (B ₁ , 1 / C ₁ ). This indicates that the ink at the set point can be adjusted by adding a diluent to the ink at the evaporation point.

By the way, the proportionality constant (gradient α ₁ ) of the characteristic T ₁ varies depending on the alcohol concentration N of the diluent to be added. Assuming that the alcohol concentration of the diluent having the characteristic T ₁ is the concentration N ₁ , the characteristic T ₁ ′ indicated by a broken line is a case where a diluent having a lower concentration than the alcohol concentration N ₁ is used, and the gradient thereof is the gradient α _1. Is smaller than On the contrary, the characteristic (T ₁ ″) indicated by the broken line is a case where a diluent having a higher concentration than the alcohol concentration N ₁ is used, and the gradient thereof is larger than the gradient α ₁ . Thus, the gradient α ₁ increases as the alcohol concentration N of the diluent increases (see arrow A6).

In the characteristic T ₁ ′, the cut rate B ₁ ′ when (1 / conductivity C) is equal to the set point (1 / conductivity C ₁ ) is larger than the set point cut rate B ₁ . This indicates that more than the added amount of the diluent is characteristic T _1. Conversely, in the characteristic T ₁ ″, the cut rate B ₁ ″ when (1 / conductivity C) is equal to the set point (1 / conductivity C ₁ ) is smaller than the set point cut rate B _1. ing. This indicates that less than the addition amount of the diluent is characteristic T _1.

From the above, when a diluent is added to the ink at the evaporation point, a relatively high concentration of diluent is added even if a relatively low concentration of diluent is added (characteristic T ₁ ′). It can be seen that even if a relatively small amount is added (characteristic T ₁ ″), it can be equal to the set point (1 / conductivity C ₁ ). In other words, when adding a diluent (alcohol aqueous solution) for the purpose of adjusting from the evaporation point to the set point, simply adopting a method of adjusting only the conductivity C to the set point C ₁ , the alcohol concentration N of the diluent and There will be many (in theory, infinite) combinations with the amount of diluent. Therefore, such a simple method does not guarantee that the set point can be reliably adjusted.

FIG. 2B is a diagram showing the relationship between the alcohol concentration N of the diluent and the gradient α of the characteristic T ₁ shown in FIG. As shown in the characteristic F ₁ , the gradient α and the alcohol concentration N have a linear function (α = β ₁ · N + γ ₁ ), and the gradient α = α ₁ when the alcohol concentration N = N ₁ . . The sign of the gradient β ₁ of this linear function is positive (β ₁ > 0).

  From the above, the following equations can be derived.

Δ (1 / C) = α · (ΔB) (Formula 1)
However, ΔB = (Δw + Δh) / M (Formula 2)
α = β ₁ · N + γ ₁ (Formula 3)
However, N = Δh / (Δw + Δh) (Formula 4)
Here, Δ (1 / C) is an increment (first change amount) of 1 / (conductivity C) due to the addition of diluent, ΔB is an increment of cut rate B due to the addition of diluent, and Δw is The mass of water in the added diluent, Δh is the mass of alcohol in the added diluent. From the viewpoint of change from the set point to the evaporation point, Δw is the mass of water evaporated from the set point, and Δh is the mass of alcohol evaporated from the set point. M is a mass corresponding to the undiluted ink contained in the ink to be adjusted.

  Further, the following equations can be derived from (Equation 1) to (Equation 4).

_{Δ (1 / C) = b} 11 · Δh + b 12 · Δw ··· ( Formula 5: first equation)
Where b ₁₁ (constant) = (β ₁ + γ ₁ ) / M (Expression 6)
b ₁₂ (constant) = γ ₁ / M (Expression 7)
Incidentally, if the mass M is constant, the constant _{b 11} and _{b 12} are the constants inherent to the ink.

  On the other hand, FIG. 3 is a diagram showing the dilution characteristics of ink, (a) is the relationship between the cut rate B and the viscosity V (second physical quantity), and (b) is a diluent (alcohol) in the characteristics shown in (a). The relationship between the alcohol concentration N of the aqueous solution) and the characteristic gradient α is shown.

FIG. 3A shows the ink cut rate B as the dilution degree on the horizontal axis. The cut rate B ₁ is the set point cut rate, and the cut rate B ₀ is the evaporation point cut rate. The vertical axis of FIG. 3A shows the reciprocal of the viscosity V, that is, 1 / (viscosity V). Viscosity V ₁ is the set point viscosity and viscosity V ₀ is the evaporation point viscosity.

Therefore, the characteristics shown in FIG. 3A are based on the evaporation point (B ₀ , 1 / V ₀ ), and the cut rate B and 1 / (viscosity when a diluent is added to the ink at the evaporation point. V). The characteristic T ₂ indicated by the solid line passes through the set point (B ₁ , 1 / V ₁ ). This indicates that the ink at the set point can be adjusted by adding a diluent to the ink at the evaporation point.

By the way, the proportionality constant (gradient α ₂ ) of the characteristic T ₂ varies depending on the alcohol concentration N of the diluent to be added. Assuming that the alcohol concentration of the diluent having the characteristic T ₂ is the concentration N ₁ , the characteristic T ₂ ′ indicated by a broken line is a case where a diluent having a lower concentration than the alcohol concentration N ₁ is used, and the gradient thereof is the gradient α _2. Is bigger than. On the contrary, the characteristic (T ₂ ″) indicated by the broken line is a case where a diluent having a concentration higher than the alcohol concentration N ₁ is used, and the gradient thereof is smaller than the gradient α ₂ . Thus gradient alpha ₂ is smaller the higher the alcohol concentration N of the diluent (see arrow A7).

In the characteristic T ₂ ′, the cut rate B ₂ ′ when (1 / viscosity V) is equal to the set point (1 / viscosity V ₁ ) is smaller than the set point cut rate B ₁ . This indicates that less than the addition amount of the diluent is characteristic T _2. Conversely, in the characteristic T ₂ ″, the cut rate B ₂ ″ when (1 / viscosity V) is equal to the set point (1 / viscosity V ₁ ) is larger than the set point cut rate B ₁ . . This indicates that more than the added amount of the diluent is characteristic T _2.

From the above, when a diluent is added to the ink at the evaporation point, a relatively low concentration of diluent is compared even if a relatively small amount of diluent is added (characteristic T ₂ ′). It can be seen that even if a large amount is added (characteristic T ₂ ″), it can be made equal to the set point (1 / viscosity V ₁ ). In other words, when adding a diluent (alcohol aqueous solution) for the purpose of adjusting from the evaporation point to the set point, simply adopting a method in which only the viscosity V is adjusted to the set point V ₁ , the alcohol concentration N of the diluent and the dilution There are many (in theory, infinite) combinations with the amount of agent. Therefore, such a simple method does not guarantee that the set point can be reliably adjusted.

FIG. 3B is a diagram showing the relationship between the alcohol concentration N of the diluent and the gradient α ′ of the characteristic T ₂ shown in FIG. As shown in the characteristic F ₂ , the gradient α ′ and the alcohol concentration N have a linear function (α ′ = β ₂ · N + γ ₂ ), and when the alcohol concentration N = N ₁ , the gradient α ′ = α ₂ It has become. The sign of the gradient β ₂ of this linear function is negative (β ₂ <0).

  From the above, the following equations can be derived.

Δ (1 / V) = α ′ · (ΔB) (Expression 11)
α ′ = β ₂ · N + γ ₂ (Formula 12)
Here, Δ (1 / V) indicates an increment (second variation) of 1 / (viscosity V) due to the addition of the diluent.

  Furthermore, the following equations can be derived from (Equation 2), (Equation 4), (Equation 11), and (Equation 12).

Δ (1 / V) = b ₂₁ · Δh + b ₂₂ · Δw (Equation 13: second equation)
Where b ₂₁ (constant) = (β ₂ + γ ₂ ) / M (Expression 14)
b ₂₂ (constant) = γ ₂ / M (Expression 15)
If the mass M is constant, the constants b ₂₁ and b ₂₂ are constants specific to the ink.

  When the simultaneous equations of the first equation (Equation 5) and the second equation (Equation 13) are solved, the following equations (solutions of the simultaneous equations) are obtained.

_{Δh = (b 22 · Δ (} 1 / C) -b 12 · Δ (1 / V)) / Φ 1 ··· ( Formula 21)
Δw = (− b ₂₁ · Δ (1 / C) + b ₁₁ · Δ (1 / V)) / Φ ₁ (Equation 22)
However [Phi _{1 (constant) = b 11 · b 22 -b} 12 · b 21 ··· ( Formula 23)
As can be seen from (Equation 21) to (Equation 23), Δ (1 / C) and Δ (1 / V) are measured if the constants b ₁₁ , b ₁₂ , b ₂₁ and b ₂₂ are obtained in advance. Thus, the mass Δh of alcohol evaporated from the set point and the mass Δw of water evaporated from the set point can be calculated independently.

FIG. 4 is a diagram in which FIG. 2B and FIG. 3B are superimposed. However, they are superimposed after appropriately adjusting the scales of the vertical axes α and α ′ so that the gradient α ₁ and the gradient α ₂ are at the same position on the vertical axis. The effect of with reference to FIG gradient beta ₁ of a linear function F ₁ and slope beta ₂ linear functions F ₂ and positive and negative inverse slope to each other will be described.

As shown in FIG. 4, the linear function F ₁ and the linear function F ₂ intersect at one point, that is, the set point (N ₁ , α ₁ ). That keep the component ratio of the ink to set point when the alcohol and water in the ink alcohol concentration N evaporates becomes vaporization point changed to N _0, for example, from N _1, the change in the alcohol concentration N It is none other than adding alcohol and water in a direction to offset the amount ΔN. Therefore, practically, it is desirable that the accuracy of the intersection (target set point) between the linear function F ₁ and the linear function F ₂ is high. For this purpose, it is desirable that the linear function F ₁ and the linear function F ₂ do not have characteristics close to parallel. This is because when the linear function F ₁ and the linear function F ₂ have characteristics close to parallel, it is easy to divide by a small value close to 0 in the calculation process, and practical accuracy is lowered. In this respect, in the present embodiment, since the gradients β ₁ and β _{2 of the} linear function are mutually positive and negative gradients, such a situation hardly occurs. Therefore, the practical accuracy of the solution of the equations shown in (Expression 21) and (Expression 22) can be increased.

  The above is the explanation of the principle. As described above, the mass Δh of alcohol evaporated from the set point and the mass Δw of water evaporated from the set point are independently calculated by (Equation 21) and (Equation 22). Therefore, in the adjustment, an amount of alcohol equal to the amount of alcohol evaporation Δh and an amount of water equal to the amount of water evaporation Δw may be added.

However, in this embodiment, the alcohol aqueous solution is directly added from the high concentration tank 15 and the low concentration tank 16. The concentration n ₂ of the low concentration tank 16 can be 0% (that is, water), but the concentration n ₁ of the high concentration tank 15 needs to be 90% or less in order to prevent the quality of the ink as described above. Therefore, in the present embodiment, a method of adding the necessary amounts of alcohol and water more simply is adopted by modifying the above (formula 5) to (formula 22) as follows.

In the above description of the principle, it was considered that the evaporation point is that the alcohol is evaporated by Δh and water by Δw from the set point. This is because the alcohol aqueous solution with high concentration n ₁ is ΔQ ₁ and the alcohol aqueous solution with low concentration n ₂ . Is evaporated by ΔQ ₂ . In other words, the following formulas are considered.

Δh = n ₁ · ΔQ ₁ + n ₂ · ΔQ ₂ (Equation 31)
Δw = (1−n ₁ ) · ΔQ ₁ + (1−n ₂ ) · ΔQ ₂ (Expression 32)
Then, by substituting (Equation 31) and (Equation 32) into (Equation 5) and (Equation 13), respectively, the following equations are obtained.

Δ (1 / C) = a ₁₁ · ΔQ ₁ + a ₁₂ · ΔQ ₂ (Expression 33)
Δ (1 / V) = a ₂₁ · ΔQ ₁ + a ₂₂ · ΔQ ₂ (Expression 34)
However _{a 11 (constant) = b 11 · n 1 +} b 12 · (1-n 1) ··· ( Formula 35)
a ₁₂ (constant) = b ₁₁ · n ₂ + b ₁₂ · (1−n ₂ ) (Formula 36)
a ₂₁ (constant) = b ₂₁ · n ₁ + b ₂₂ · (1-n ₁ ) (Expression 37)
a ₂₂ (constant) = b ₂₁ · n ₂ + b ₂₂ · (1-n ₂ ) (Formula 38)
Furthermore, when the simultaneous system of (Expression 33) and (Expression 34) is solved, the following respective expressions (solutions of simultaneous equations) are obtained.

ΔQ ₁ = (a ₂₂ · Δ (1 / C) −a ₁₂ · Δ (1 / V)) / Φ (Formula 41)
ΔQ ₂ = (− a ₂₁ · Δ (1 / C) + a ₁₁ · Δ (1 / V)) / Φ (Formula 42)
Where Φ (constant) = a ₁₁ · a ₂₂ −a ₁₂ · a ₂₁ (Equation 43)
As can be seen from (Expression 41) to (Expression 43), Δ (1 / C) and Δ (1 / V) are measured if the constants a ₁₁ , a ₁₂ , a ₂₁ and a ₂₂ are obtained in advance. by, it can be calculated independently and mass Delta] Q ₂ of the aqueous alcohol mass Delta] Q ₁ and concentration n ₂ of the vaporized to (and thought) concentration n ₁ alcohol aqueous solution from the set point.

So adjustments when the high concentration alcohol aqueous solution of the mass Delta] Q ₁ from the high-concentration tank 15, a low concentration alcohol mass Delta] Q ₂ from low concentration tank 16, may be added respectively.

If concentration n ₁ = concentration n ₂ is assumed, from (Expression 35) to (Expression 38), a ₁₁ = a ₁₂ and a ₂₁ = a ₂₂ are obtained. Therefore, Φ = 0 from (Equation 43). In this case, as is clear from (Expression 41) and (Expression 42), the equation does not have a unique solution. That is, the evaporation amounts ΔQ ₁ and ΔQ ₂ cannot be calculated independently. In this embodiment, since concentration n ₁ > concentration n ₂ , such a situation does not occur, and a solution (each evaporation amount ΔQ ₁ , ΔQ ₂ ) can be obtained with high accuracy.

FIG. 5 is a schematic flowchart of ink component adjustment control by the arithmetic control unit 4 of the apparatus. Next, the operation of the ink component adjusting device will be described with reference to this flowchart. The flowchart shown in FIG. 5 is for the case where the constants (a ₁₁ , a ₁₂ , a ₂₁ , a ₂₂ ) specific to the ink are used and the initial state of printing is set as the set point. This control is performed in parallel with the operation of the printing press including the ink tank 6.

  When this flow starts, first, in step S1, the switching valve 5 is switched to the open circuit 31 side. As a result, the ink circulates in the open circuit 31 including the ink tank 6 and is homogenized.

  Next, in step S3, the switching valve 5 is switched to the closed circuit 32 side, and the temperature regulator 3 is operated. Thereby, the temperature of the ink in the closed circuit 32 is kept constant (for example, 20 ° C.).

In step S5, the conductivity of the initial C ₁ and the viscosity V ₁ is measured. Specifically, the conductivity C ₁ of the ink in the measurement chamber 2 is measured by the conductivity sensor 18, and the viscosity V ₁ of the circulating ink is measured from the pulsation number of the diaphragm pump 1 based on the signal from the pressure sensor 17. Is done. These conductivity C ₁ and viscosity V ₁ are stored in the storage unit of the arithmetic control unit 4 as set point values.

Next, in step S7, the arithmetic control unit 4 opens a solenoid valve (not shown) and adds a predetermined amount (ΔQ ₁₁ and ΔQ ₂₂ ) of an alcohol aqueous solution from the low concentration tank 16 and the high concentration tank 15 into the suction hose 8, respectively. . And measuring the electrical conductivity _C 2, _{C 3} and viscosity _V 2, _{V 3} after being changed by the addition. Further, constants (a ₁₁ , a ₁₂ , a ₂₁ , a ₂₂ ) specific to the ink are calculated from the measurement results. Specifically, the following procedure is followed.

The arithmetic control unit 4 first opens the solenoid valve of the high concentration tank 15 and adds a high concentration n ₁ alcohol aqueous solution by ΔQ ₁₁ into the suction hose 8. And measuring the electrical conductivity C ₂ and a viscosity V ₂ after the addition. The arithmetic control unit 4 obtains the first change amount Δ (1 / C) ₂ and the second change amount Δ (1 / V) ₂ based on the value and the set value by the following equations.

Δ (1 / C) ₂ = 1 / C ₂ −1 / C ₁ (Formula 51)
Δ (1 / V) ₂ = 1 / V ₂ −1 / V ₁ (Formula 52)
Then, the arithmetic control unit 4 substitutes Δ (1 / C) ₂ for Δ (1 / C) in (Equation 33), ΔQ ₁₁ for ΔQ ₁ , and 0 for ΔQ ₂ , thereby obtaining a constant a ₁₁ = Δ (1 / C) ₂ / ΔQ ₁₁ is obtained and stored.

Similarly, the arithmetic control unit 4 substitutes Δ (1 / V) ₂ for Δ (1 / V) in (Equation 34), ΔQ ₁₁ for ΔQ ₁ , and 0 for ΔQ ₂ , thereby obtaining a constant a _21. = Δ (1 / V) ₂ / ΔQ ₁₁ is obtained and stored.

Next, the arithmetic control unit 4 opens the electromagnetic valve of the low concentration tank 16 and adds a low concentration n ₂ alcohol aqueous solution by ΔQ ₂₂ into the suction hose 8. Then, the conductivity C ₃ and the viscosity V ₃ after the addition are measured. The arithmetic control unit 4 calculates the first change amount Δ (1 / C) ₃ and the second change amount Δ (1 / V) ₃ by the following equations.

Δ (1 / C) ₃ = 1 / C ₃ −1 / C ₂ (Formula 53)
Δ (1 / V) ₃ = 1 / V ₃ −1 / V ₂ (Formula 54)
Next, the arithmetic control unit 4 substitutes Δ (1 / C) ₃ for Δ (1 / C) in (Equation 33), 0 for ΔQ ₁ , and ΔQ ₂₂ for ΔQ ₂ , thereby obtaining a constant a ₁₂ = Δ (1 / C) ₃ / ΔQ ₂₂ is obtained and stored.

Similarly, the arithmetic control unit 4 substitutes Δ (1 / V) ₃ for Δ (1 / V) in (Equation 34), 0 for ΔQ ₁ , and ΔQ ₂₂ for ΔQ ₂ , thereby obtaining a constant a _22. = Δ (1 / V) ₃ / ΔQ ₂₂ is obtained and stored.

  Next, in step S9, the switching valve 5 is switched to the open circuit 31 side. Thus, fresh ink from the ink tank 6 is guided to the suction hose 8, the discharge hose 9, and the discharge hose 10 (path corresponding to the closed circuit 32).

  Next, in step S11, it is determined whether or not a predetermined time has elapsed. This predetermined time is a time set in advance as an interval period for performing component adjustment. If NO is determined in step S11, the process waits. If YES is determined, the process proceeds to the next step. At this time, a certain amount of alcohol and water is evaporated from the ink due to the circulation of the open circuit 31 accompanying the printing. That is, the ink is an evaporation point ink.

  Next, in step S13, the switching valve 5 is switched to the closed circuit 32 side, and the temperature regulator 3 is operated. Thereby, the temperature of the ink in the closed circuit 32 is kept constant (for example, 20 ° C.).

Next, in step S15, the conductivity C ₀ and the viscosity V ₀ of the evaporation point are measured. Specifically, the conductivity C ₀ of the ink in the measurement chamber 2 is measured by the conductivity sensor 18, and the viscosity V ₀ of the circulating ink is measured from the pulsation number of the diaphragm pump 1 based on the signal from the pressure sensor 17. Is done.

In the next step S17, an alcohol evaporation amount Δh and a water evaporation amount Δw for an amount of ink corresponding to the volume of the closed circuit 32 are obtained. These values are specifically evaporation Delta] Q 1 of the high-concentration n ₁ aqueous alcohol solution _is obtained as the evaporation amount Delta] Q ₂ of the low-concentration n ₂ aqueous alcohol solution. First, the first change amount Δ (1 / C) ₀ from the conductivity C ₀ and the viscosity V _{0 of} the evaporation point measured in step S15 and the conductivity C ₁ and the viscosity V _{1 of} the set point measured in step S5. And the second change amount Δ (1 / V) ₀ are obtained by the following equations.

Δ (1 / C) ₀ = 1 / C ₁ −1 / C ₀ (Expression 55)
Δ (1 / V) ₀ = 1 / V ₁ −1 / V ₀ (Formula 56)
Then, Δ (1 / C) ₀ is substituted into Δ (1 / C) of (Equation 41) to (Equation 43), and Δ (1 / V) ₀ is substituted into Δ (1 / V), respectively, and a _{11 to} a by substituting the values obtained in step S7 to _22, alcohol evaporation amount Δh and evaporation of the alcohol solution of the evaporation Delta] Q ₁ and the low concentration n ₂ of the high concentration n ₁ alcohol aqueous solution, corresponding to a water evaporation amount Δw ΔQ ₂ is obtained.

In the next step S21, with the switching valve 5 is switched to an open circuit 31 side, the high concentration alcohol aqueous solution of the mass Delta] Q ₁ from the high-concentration tank 15 to the ink in the suction hose 8 is, from the low concentration tank 16 mass Delta] Q ₂ A low concentration aqueous alcohol solution is added simultaneously. These additions are gradually performed according to the circulation speed of the ink. Specifically, the flow rate detected from the number of pulsations of the diaphragm pump 1 is referred to, and an amount of ink corresponding to the volume in the closed circuit 32 is added over a period of time passing through the addition position (suction hose 8).

  Thus, by simultaneously adding the high-concentration alcohol aqueous solution and the low-concentration alcohol aqueous solution, ink dilution unevenness (temporal unevenness) is suppressed. That is, for example, when a method such as adding a high-concentration alcohol aqueous solution first and then adding a low-concentration alcohol aqueous solution is taken, the alcohol concentration in the diluent is once diluted after the set point becomes higher. Follow the course of convergence to the set point. On the other hand, if high-concentration and low-concentration aqueous alcohol solutions are added simultaneously, the change in alcohol concentration in the diluent converges gently and quickly from the evaporation point to the set point without wavering. Therefore, the diluted state of the ink used for printing becomes more stable, and the deterioration of print quality can be prevented.

  Further, by adding the aqueous alcohol solution while circulating the ink in the open circuit 31, the ink dilution unevenness (spatial unevenness) is suppressed. The added aqueous alcohol solution does not immediately spread into the open circuit 31, but the degree of dilution of the ink differs depending on the location (spatial unevenness) until the ink becomes homogeneous. By adding the ink while circulating it, the uneven distribution of alcohol and water is effectively suppressed, and this spatial unevenness can be reduced. In particular, as in this embodiment, if the amount of ink to be adjusted (corresponding to the volume of the closed circuit 32) is gradually added over a period of time passing through the addition position (suction hose 8), locally Even if it sees, an ink is not diluted by the dilution degree exceeding a set point, but it is more effective.

As described above, since uneven dilution of ink in terms of time and space is suppressed, the diluted state of the ink used for printing becomes more stable, and deterioration of the print quality is prevented. Such an addition method can be performed by simultaneously obtaining the alcohol evaporation amount Δh and the water evaporation amount Δw by (Equation 21) and (Equation 22) (practically (Equation 41) and (Equation 42) determine the amount of evaporation Delta] Q ₁ and evaporation amount Delta] Q ₂ of the low concentration alcohol aqueous solution at the same time), because have previously beginning of at least added, to confirm the respective amount equal to the amount of evaporation thereof.

Note that the addition amount ΔQ ₁ of the high-concentration alcohol aqueous solution and the addition amount ΔQ ₂ of the low-concentration alcohol aqueous solution (alcohol evaporation amount Δh and water evaporation amount Δw) are determined by the amount of alcohol or water evaporation relative to the ink amount in the open circuit 31. Rather, the amount corresponds to the amount of alcohol or water evaporated relative to the amount of ink in the closed circuit 32. Such a method is suitable when the amount of ink in the open circuit 31 is not constant but varies. Since the ink amount in the closed circuit 32 is constant even if the ink amount in the open circuit 31 fluctuates, the constants (a ₁₁ , a ₁₂ , a ₂₁ , a ₂₂ ) specific to the ink can be fixed values. is there.

  When the addition of each aqueous alcohol solution is completed, it is next determined in step S25 whether or not a predetermined time has elapsed. This predetermined time is a time set in advance as a period required to homogenize the ink in the open circuit 31. If NO is determined in step S25, the process waits. If YES is determined, the process proceeds to step S27. In step S27, the switching valve 5 is switched to the closed circuit 32 side, and the temperature is adjusted by the temperature controller 3. Then, the process returns to step S7, and thereafter, the routine from step S7 to step S27 is repeated. This repetition is performed until the apparatus is stopped. By sequentially adjusting the components in this way, the ink components can always be maintained near the set state.

By the way, as shown in (Expression 35) to (Expression 38), the constants (a ₁₁ , a ₁₂ , a ₂₁ , a ₂₂ ) include the concentrations n ₁ and n ₂ . That is, if the alcohol concentration in the high concentration tank 15 or the low concentration tank 16 changes, the constants (a ₁₁ , a ₁₂ , a ₂₁ , a ₂₂ ) also change. In the present embodiment, each constant (a ₁₁ , a ₁₂ , a ₂₁ , a ₂₂ ) is updated every time by returning from step S27 to step S7. As a result, even if alcohol or water evaporates from the alcohol aqueous solution in the tanks 15 and 16 and the alcohol concentration changes, appropriate constants (a ₁₁ , a ₁₂ , a ₂₁ , a ₂₂ ), the respective evaporation amounts ΔQ ₁ and ΔQ ₂ can be obtained with high accuracy.

In other words, in this embodiment, the evaporation amounts ΔQ ₁ and ΔQ ₂ can be obtained even if the alcohol concentration in each of the tanks 15 and 16 is unknown. Therefore, it is not necessary to strictly manage the alcohol concentration in each of the tanks 15 and 16, so that the apparatus can be simplified.

If the alcohol concentration in each of the tanks 15 and 16 is controlled to be constant, the constants (a ₁₁ , a ₁₂ , a ₂₁ , a ₂₂ ) are fixed values. You may make it return to S15.

As is apparent from the above description, the ink component adjusting apparatus measures the first physical quantity (conductivity) and the second physical quantity (viscosity), and determines the alcohol evaporation amount (Δh) from the change amount with respect to the set state. And the water evaporation amount (Δw), specifically, the amounts Q ₁ and Q ₂ of the respective alcohol aqueous solutions corresponding to them are calculated, and the addition amount of alcohol and water equal to the evaporation amount, actually two different concentrations Thus, an appropriate amount of alcohol and water can be easily added.

  The embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the invention described in the claims.

  For example, in the present embodiment, the conductivity C and the viscosity V are measured at a constant temperature using the temperature controller 3, but when the temperature correction is possible or the entire apparatus is maintained at a constant temperature. In this case, the temperature controller 3 may be omitted.

In this embodiment, the switching valve 5 switches between the open circuit 31 and the closed circuit 32. By switching to the closed circuit 32, the efficiency of temperature adjustment by the temperature regulator 3 is improved, and the amount of ink to be adjusted can be made constant, that is, the constants a ₁₁ , a ₁₂ , a ₂₁ , and a ₂₂ are the temperatures. There is an advantage that fluctuation due to change can be suppressed. Therefore, when there is no such request, for example, when the temperature controller 3 is not used and the ink amount in the open circuit 31 does not vary, the switching valve 5 is omitted, and all the circuits are in the open circuit 31 state. You can go.

  The alcohol concentration in the low concentration tank 16 may be 0%, that is, the water may be stored in the tank. When the alcohol concentration in the low concentration tank 16 is lowered, there is an advantage that the adjustment range of the addition ratio of alcohol and water can be increased. Further, when the alcohol concentration of the low concentration tank 16 is increased to approach the alcohol concentration of the high concentration tank 15, the amount of addition from the high concentration tank 15 is relatively reduced, so that when the high concentration aqueous alcohol solution is added to the ink, Heat generation can be suppressed.

The set point does not necessarily have to be in the initial state. For example, it is also possible to use those devices in some cases the ink the predetermined setpoint (conductivity C ₁ and the viscosity V ₁ and the like known) as diluted to.

It is a schematic block diagram of the component adjustment apparatus of the water-based ink which concerns on one Embodiment of this invention. It is a figure which shows the dilution characteristic of ink, (a) is the relationship between a dilution degree (cut rate) and electrical conductivity, (b) is the alcohol density | concentration of the diluent (alcohol aqueous solution) in the characteristic shown to (a), The relationship with the characteristic gradient is shown. It is a figure which shows the dilution characteristic of ink, (a) is the relationship between a cut rate and a viscosity, (b) is the characteristic shown to (a), the alcohol concentration of a diluent (alcohol aqueous solution), and the gradient of a characteristic. Show the relationship. It is the figure which piled up Drawing 2 (b) and Drawing 3 (b). 3 is a schematic flowchart of ink component adjustment control by an arithmetic control unit of the ink component adjustment apparatus shown in FIG. 1.

1 Diaphragm pump ( second physical quantity measuring means)
4. Calculation control unit (calculation means , second physical quantity measurement means, addition means)
15 High concentration tank (addition means)
16 Low concentration tank (addition means)
17 Pressure sensor ( second physical quantity measuring means, pulsation number measuring means)
18 Conductivity sensor ( first physical quantity measuring means)
B cut rate C conductivity (first physical quantity)
F ₁ , F ₂ linear function N alcohol concentration V viscosity (second physical quantity)
Δh alcohol evaporation amount Δw water evaporation amount Δ (1 / C) first change amount Δ (1 / V) second change amount ΔQ ₁ evaporation amount of high concentration alcohol aqueous solution, addition amount ΔQ ₂ evaporation amount of low concentration alcohol aqueous solution, Addition amount β ₁ , β ₂ linear function gradient

Claims (5)

A component adjustment device for maintaining the component ratio of water-based ink containing an aqueous alcohol solution in the vicinity of a predetermined setting state,
A first physical quantity measuring means for measuring the conductivity of the water-based ink as the first physical quantity of the water- based ink to be adjusted, which varies depending on the alcohol evaporation amount and water evaporation amount from the ink;
A second physical quantity measuring means for measuring the viscosity of the water-based ink as the second physical quantity of the water- based ink to be adjusted, which changes according to the amount of alcohol evaporated from the ink and the amount of water evaporated;
A calculating means for calculating an evaporation amount of alcohol and water of the water-based ink to be adjusted from a change amount of the first physical quantity and the second physical quantity with respect to the set state;
An adding means for adding alcohol and water in an amount equal to each evaporation amount to the water-based ink to be adjusted;
The adding means includes a high concentration tank for storing a relatively high concentration aqueous alcohol solution, and a low concentration alcohol solution or a low concentration tank for storing water lower than the alcohol aqueous solution in the high concentration tank. By adding an alcohol aqueous solution from the tank and an alcohol aqueous solution from the low-concentration tank in an appropriate ratio, an amount of alcohol and water equal to each of the above evaporation amounts is added,
The calculation means includes a first equation that expresses a first change amount uniquely determined from a change from the set state of the first physical quantity as a variable of a water evaporation amount and an alcohol evaporation amount, and the second physical quantity. The second change amount that is uniquely determined from the change from the set state is determined in accordance with the principle of obtaining a solution of a simultaneous equation with the second equation that represents the water evaporation amount and the alcohol evaporation amount as variables . The addition amount from the high-concentration tank and the addition amount from the low-concentration tank, which are equivalent to the amount of alcohol and water equal to each evaporation amount, are calculated independently by an arithmetic expression . A component adjustment device for water-based ink.   The first change amount and the second change amount are respectively obtained when diluting the water-based ink at the evaporation point where an arbitrary amount of alcohol and an arbitrary amount of water have evaporated from the set state with a diluent comprising an alcohol aqueous solution having a predetermined concentration. 2. The water-based ink component adjusting device according to claim 1, wherein the proportion constant is a linear function of the alcohol concentration of the diluent.   3. The water-based ink component adjustment apparatus according to claim 2, wherein the first change amount and the second change amount are such that the slopes of the linear functions are positive and negative slopes. In the water-based ink component adjustment apparatus according to claim 3,
The calculation means includes the first change amount and the second change amount when a predetermined amount of the alcohol aqueous solution is added from the high concentration tank, and the case where the predetermined amount of the alcohol aqueous solution or water is added from the low concentration tank. Based on the first change amount and the second change amount, a plurality of constants specific to the water-based ink are obtained, and the addition amount from the high concentration tank and the low concentration tank are calculated by an arithmetic expression using the plurality of constants. A water-based ink component adjusting device, wherein the amount of water added is calculated. The second physical quantity measuring means is
A diaphragm pump for circulating the water-based ink to be adjusted;
5. The water-based ink component adjustment apparatus according to claim 1, further comprising a pulsation number measuring unit configured to measure the pulsation number of the diaphragm pump.

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