WO2016163167A1 - Chemical heat-storage device - Google Patents

Abstract

This chemical heat-storage device 11 is provided with a controller 24 which, when NH₃ is supplied to a reactor 12 from an adsorber 13, obtains the pressure change amount inside the adsorber 13 on the basis of the pressure inside the adsorber 13, and sets the NH₃ adsorption amount of the adsorber 13, which is estimated using the pressure inside the adsorber 13 when the pressure change amount is equal to or less than a threshold value P, to the NH₃ adsorption amount of the adsorber 13 during a state in which the NH₃ recovery rate of the adsorber 13 is 0%. Furthermore, when NH₃ is supplied to the adsorber 13 from the reactor 12, the controller 24 obtains the pressure change amount inside the adsorber 13 on the basis of the pressure inside the adsorber 13, and sets the NH₃ adsorption amount of the adsorber 13, which is estimated using the pressure inside the adsorber 13 when the pressure change amount is equal to or less than a threshold value Q, to the NH₃ adsorption amount of the adsorber 13 during a state in which the NH₃ recovery rate of the adsorber 13 is 100%.

Description

Chemical heat storage device

The present invention relates to a chemical heat storage device.

As a conventional chemical heat storage device, for example, a device described in Patent Document 1 is known. The chemical heat storage device described in Patent Document 1 is disposed on the entire outer surface of the diesel oxidation catalyst, and includes a reactor having a reaction material that chemically reacts with ammonia (NH ₃ ), and an adsorbent that physically adsorbs NH _3. An adsorber and a connection line for moving NH ₃ between the reactor and the adsorber are provided. When the temperature of the exhaust gas exhausted from the engine is lower than a predetermined temperature, NH ₃ is moved from the adsorber to the reactor to cause a chemical reaction between the NH ₃ and the reactant, and heat is generated. It is transmitted to the diesel oxidation catalyst, and the diesel oxidation catalyst is heated. When the temperature of the exhaust gas exhausted from the engine becomes higher than a predetermined temperature, the exhaust heat of the exhaust gas is given to the reaction material of the reactor, whereby NH ₃ and the reaction material are separated, and the separated NH ₃ is separated from the reactor. It is collected in the adsorber.

JP 2014-85093 A

By the way, in the chemical heat storage device as in the above prior art, if the recovery control is terminated in a state where the recovery amount of NH ₃ (reaction medium) to the adsorber is insufficient, the adsorber is used in the subsequent heat generation control. Even if NH ₃ is supplied from the reactor to the reactor, the amount of NH ₃ is small, so that a sufficient amount of heat cannot be generated from the reaction material. In order to deal with such a problem, for example, it is conceivable that the completion of recovery in the recovery control of the adsorber is determined based on the NH ₃ recovery rate of the adsorber. Further, the failure detection of the NH ₃ supply system may be performed based on the NH ₃ recovery rate of the adsorber. Therefore, in order to accurately perform the recovery completion determination and the failure detection, the reference value for calculating the NH ₃ recovery rate of the adsorber, that is, the state where the NH ₃ recovery rate of the adsorber is 0% and 100% It is necessary to accurately recognize the NH ₃ adsorption amount of the adsorber in each of the states.

An object of the present invention is to provide a chemical heat storage device capable of accurately recognizing the amount of adsorbing reaction medium adsorbed in each of the adsorber reaction medium recovery rate of 0% and 100%. .

A chemical heat storage device according to one aspect of the present invention generates heat and is heated by a chemical reaction between an adsorber having an adsorbent capable of adsorbing and desorbing a reaction medium and the reaction medium. A reactor having a reaction material that absorbs heat and desorbs the reaction medium, a supply pipe that connects the adsorber and the reactor so that the reaction medium can flow between the adsorber and the reactor, and an adsorption When the reaction medium is supplied from the adsorber to the reactor, the pressure change amount per unit time in the adsorber is obtained based on the pressure in the adsorber. The adsorber reaction medium adsorption amount estimated by using the pressure in the adsorber when the amount of pressure change per unit time in the adsorber becomes equal to or less than the first predetermined value is the reaction medium recovery rate of the adsorber. A first setting unit for setting the amount of adsorption of the reaction medium of the adsorber in a state of 0%; When the reaction medium is supplied from the reactor to the adsorber, the pressure change amount per unit time in the adsorber is obtained based on the pressure in the adsorber, and the pressure change amount per unit time in the adsorber is the second. Set the adsorbent reaction medium adsorption amount estimated using the pressure in the adsorber when the pressure falls below the specified value to the adsorber reaction medium adsorption amount when the adsorber reaction medium recovery rate is 100%. And a second setting unit.

In such a chemical heat storage device, when the reaction medium is supplied from the adsorber to the reactor, the pressure in the adsorber gradually decreases with the passage of time, and the pressure per unit time in the adsorber after a certain period of time. The amount of change becomes smaller. Therefore, the adsorber reaction medium adsorption amount estimated using the pressure in the adsorber when the pressure change amount per unit time in the adsorber becomes equal to or less than the first predetermined value is used as the reaction medium recovery of the adsorber. It is set to the reaction medium adsorption amount of the adsorber in a state where the rate is 0%. Thereby, the reaction medium adsorption amount of the adsorber when the reaction medium recovery rate of the adsorber is 0% can be accurately recognized. On the other hand, when the reaction medium is supplied from the reactor to the adsorber, the pressure in the adsorber gradually increases with the passage of time, and the amount of pressure change per unit time in the adsorber decreases after a certain period of time. Therefore, the adsorber reaction medium adsorption amount estimated using the pressure in the adsorber when the pressure change amount per unit time in the adsorber becomes the second predetermined value or less is used as the reaction medium recovery of the adsorber. It is set to the reaction medium adsorption amount of the adsorber when the rate is 100%. Thereby, the reaction medium adsorption amount of the adsorber when the reaction medium recovery rate of the adsorber is 100% can be accurately recognized.

The first setting unit estimates a reaction medium adsorption amount of the adsorber as a first update value using a pressure in the adsorber when a pressure change amount per unit time in the adsorber becomes equal to or less than a first predetermined value. The reaction medium adsorption amount of the adsorber when the adsorber reaction medium recovery rate is 0% is corrected from the first initial value set when the adsorber is filled with the reaction medium to the first updated value, 2 The setting unit estimates the reaction medium adsorption amount of the adsorber as a second update value using the pressure in the adsorber when the pressure change amount per unit time in the adsorber becomes equal to or less than the second predetermined value. The reaction medium adsorption amount of the adsorber when the reaction medium recovery rate of the adsorber is 100% may be corrected from the second initial value set when the adsorber is filled with the reaction medium to the second updated value. . In this case, even if the initial value set when the adsorber is filled with the reaction medium deviates from the updated value estimated using the pressure in the adsorber, the reaction medium recovery rate of the adsorber is 0%. The reaction medium adsorption amount of the adsorber in each of the state and the 100% state can be accurately recognized.

The adsorber temperature acquisition unit further acquires an adsorber temperature, and the first setting unit and the second setting unit are configured to adsorb the reaction medium adsorbed on the adsorber based on the pressure in the adsorber and the temperature of the adsorber. May be estimated. In this case, the reaction medium adsorption amount of the adsorber can be easily estimated.

According to the present invention, there is provided a chemical heat storage device capable of accurately recognizing the amount of adsorption of the reaction medium of the adsorber when the reaction medium recovery rate of the adsorber is 0% and 100%.

It is a schematic block diagram which shows the exhaust gas purification system provided with one Embodiment of the chemical heat storage apparatus. It is sectional drawing of the heat exchanger and reactor shown by FIG. It is a schematic block diagram which shows the control system of the chemical heat storage apparatus shown by FIG. It is a flowchart which shows the detail of the process sequence performed by the controller shown by FIG. FIG. 4 is a conceptual diagram showing a flow of NH ₃ between the adsorber and the reactor shown in FIG. 3. NH ₃ is a graph showing an example of the saturated vapor pressure characteristics and NH ₃ adsorption properties. When the NH ₃ flow between the reactor and the adsorber is a graph showing an example of a change in adsorbed NH ₃ amount over time.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a schematic configuration diagram illustrating an exhaust purification system including an embodiment of a chemical heat storage device. In FIG. 1, an exhaust purification system 1 is provided in an exhaust system of a diesel engine 2 (hereinafter simply referred to as “engine 2”) of a vehicle, and purifies harmful substances (environmental pollutants) contained in exhaust gas discharged from the engine 2. To do.

The exhaust purification system 1 includes a heat exchanger 3, a diesel oxidation catalyst (DOC) 4, a diesel exhaust particulate removal filter (DPF) 5, a selective reduction catalyst (SCR) 6 and an ammonia slip. A catalyst (ASC: Ammonia Slip Catalyst) 7 is provided. The heat exchanger 3, the DOC 4, the DPF 5, the SCR 6, and the ASC 7 are sequentially disposed in the exhaust passage 8 connected to the engine 2 from the upstream side toward the downstream side.

As shown in FIG. 2, the heat exchanger 3 includes a cylindrical outer tube 9 and a honeycomb-structured heat exchange unit 10 disposed in the outer tube 9. The outer cylinder 9 has a function as an exhaust pipe that forms a part of the exhaust passage 8. The outer cylinder 9 is made of, for example, stainless steel. The heat exchange unit 10 exchanges heat between the exhaust gas and the reaction material 17 (described later) while the exhaust gas flows. The heat exchanging section 10 is made of ceramic such as SiSiC (non-oxide ceramic silicon carbide) having high thermal conductivity, or metal such as stainless steel having high thermal conductivity.

Returning to FIG. 1, the DOC 4 oxidizes and purifies HC, CO, and the like contained in the exhaust gas. The DPF 5 removes PM from the exhaust gas by collecting particulate matter (PM) contained in the exhaust gas. The SCR 6 reduces and purifies NO _x contained in the exhaust gas with urea or ammonia (NH ₃ ). ASC7 oxidizes NH ₃ passing through the SCR6.

The exhaust purification system 1 also includes a chemical heat storage device 11 that heats (warms up) the exhaust gas to be heated using a reversible chemical reaction without requiring external energy such as electric power. Yes. Specifically, the chemical heat storage device 11 stores the heat (exhaust heat) of the exhaust gas by separating the reaction material 17 (described later) and the reaction medium, and reacts with the reaction medium when necessary. The exhaust gas is heated by causing a chemical reaction with the material 17 to generate reaction heat. In the present embodiment, ammonia (NH ₃ ) is used as the reaction medium.

2 and 3, the chemical heat storage device 11 includes a reactor 12, an adsorber 13, and a reactor so that NH ₃ can flow between the reactor 12 and the adsorber 13. 12 and an NH ₃ supply pipe 14 for connecting the adsorber 13. The NH ₃ supply pipe 14 is provided with a valve 15 for opening and closing the NH ₃ flow path between the reactor 12 and the adsorber 13.

The reactor 12 is disposed around the heat exchanger 3. The reactor 12 includes the outer cylinder 9, the outer cylinder 16, and the reaction material 17 disposed between the outer cylinder 9 and the outer cylinder 16. The reaction material 17 is a material that generates heat due to a chemical reaction with NH ₃ when NH ₃ is supplied, and absorbs the heat when it is heated from the outside to desorb chemically adsorbed NH _3. . The outer cylinder 9 of the heat exchanger 3 also serves as a part of the reactor 12. The outer cylinder 16 is made of a metal such as stainless steel. The outer cylinder 9 and the outer cylinder 16 constitute a container 18 for accommodating the reaction material 17 together with two connecting plates (not shown) before and after connecting the two.

As the reaction material 17, a halide represented by the composition formula MXa is used. M is an alkaline earth metal such as Mg, Ca or Sr, or a transition metal such as Cr, Mn, Fe, Co, Ni, Cu or Zn. X is Cl, Br, I or the like. a is a number specified by the valence of M, and is 2 to 3.

The reaction material 17 may be in the form of powder or a press-molded body. Further, the reaction material 17 may be mixed with an additive for improving thermal conductivity. As the additive, carbon fiber, carbon bead, SiC bead, metal bead, polymer bead, polymer fiber or the like is used. Examples of the metal material of the metal beads include Cu, Ag, Ni, Ci—Cr, Al, Fe, and stainless steel.

A heat insulating material 19 is disposed between the outer cylinder 16 and the reaction material 17. As the heat insulating material 19, for example, glass wool is used. Moreover, you may comprise the heat insulating material 19 with hard heat insulating materials, such as a calcium silicate. One end portion of the NH ₃ supply pipe 14 passes through the outer cylinder 16 and the heat insulating material 19 and opens to the accommodation region of the reaction material 17. A porous body (not shown) that forms a NH ₃ flow path may be interposed between the reaction material 17 and the heat insulating material 19.

Returning to FIG. 1, the adsorber 13 has an adsorbent 20 capable of physical adsorption and desorption of NH ₃ . As the adsorbent 20, activated carbon, carbon black, mesoporous carbon, nanocarbon, zeolite, or the like is used.

In the exhaust purification system 1 provided with the chemical heat storage device 11 as described above, when the temperature of the exhaust gas discharged from the engine 2 is lower than a predetermined temperature, the valve 15 is opened, so that the adsorber 13 NH ₃ desorbed from the adsorbent 20 is supplied to the reactor 12 through the NH ₃ supply pipe 14. Then, the reaction material 17 (for example, MgCl ₂ ) and NH _{3 in the} reactor 12 chemically react with each other, and NH ₃ is chemisorbed on the reaction material 17. And the heat | fever generate | occur | produces from the reaction material 17 with the chemical reaction. That is, a reaction from the left side to the right side (exothermic reaction) in the following reaction formula (A) occurs. The heat generated from the reaction material 17 is transmitted to the heat exchanger 3, and the exhaust gas flowing through the heat exchanger 3 is heated (warmed up) by the heat. Then, the heated exhaust gas raises the DOC 4 to an activation temperature suitable for the purification of pollutants.

_{MgCl 2 + x NH 3 ⇔ Mg} (NH 3) x Cl 2 ... (A)

On the other hand, when the temperature of the exhaust gas exhausted from the engine 2 becomes equal to or higher than a predetermined temperature, the heat (exhaust heat) of the exhaust gas is applied from the heat exchanger 3 to the reaction material 17 of the reactor 12, so that the reaction material 17 NH ₃ is desorbed. That is, a reaction (regeneration reaction) from the right side to the left side in the above reaction formula (A) occurs. When the valve 15 is opened, NH ₃ desorbed from the reaction material 17 returns to the adsorber 13 through the NH ₃ supply pipe 14, and NH ₃ is physically adsorbed on the adsorbent 20 of the adsorber 13. The Thereby, NH ₃ is recovered in the adsorber 13.

As shown in FIG. 3, the chemical heat storage device 11 includes a temperature sensor 21, a temperature sensor 22 (adsorber temperature acquisition unit), a pressure sensor 23 (adsorber pressure acquisition unit), and a controller 24. ing. The temperature sensor 21 is connected to the upstream side of the heat exchanger 3 in the exhaust passage 8 and detects and acquires the temperature of the exhaust gas flowing through the upstream side of the heat exchanger 3 in the exhaust passage 8. The temperature sensor 22 is connected to the adsorber 13 and detects and acquires the temperature of the adsorber 13. The pressure sensor 23 is connected to the adsorber 13 and detects and acquires the pressure in the adsorber 13.

The controller 24 inputs the detection values of the temperature sensors 21 and 22 and the pressure sensor 23, performs a predetermined process, controls the valve 15, and the NH ₃ recovery rate of the adsorber 13 is 0% and 100%. The NH ₃ adsorption amount of the adsorber 13 in each of the states is set.

Here, in the initial state of the adsorber 13, when the valve 15 is opened, the adsorber 13 has a predetermined pressure in the reaction system including the reactor 12, the adsorber 13, and the NH ₃ supply pipe 14. The holding NH ₃ for holding pressure and the moving NH ₃ used for the chemical reaction with the reaction material 17 to obtain a desired exothermic temperature are adsorbed and held. Therefore, the NH ₃ recovery rate of the adsorber 13 is present in the adsorber 13 with respect to the total amount of NH ₃ for movement to be moved from the adsorber 13 to the reactor 12 in order to obtain a desired temperature during the exothermic reaction (recovered). E) The ratio of NH ₃ is shown. That is, the state in which the NH ₃ recovery rate of the adsorber 13 is 0% means that only the pressure holding NH ₃ is adsorbed and held in the adsorbent 20 in the adsorber 13, and the moving NH ₃ in the adsorber 13 is absorbed. Indicates that the amount of is zero. Further, the state in which the NH ₃ recovery rate of the adsorber 13 is 100% means that all of the moving NH ₃ used for heat generation in the reactor 12 is recovered in the adsorber 13 and the pressure is maintained in the adsorber 13. It shows that there is NH ₃ for use and NH ₃ for transfer. Note that the adsorbed NH ₃ amount of adsorber 13 is that the amount of NH ₃ adsorbed in the adsorbent 20 of the adsorber 13.

Controller 24, the first initial value A of the adsorbed NH ₃ amount of adsorber 13 in a state NH ₃ recovery of 0% adsorbers 13 (see FIG. 7 (a)), NH ₃ recovered adsorbers 13 The second initial value B (see FIG. 7B) of the NH ₃ adsorption amount of the adsorber 13 in a state where the rate is 100% is stored. These initial values A and B of the NH ₃ adsorption amount are set when the adsorber 13 is filled with NH ₃ . Specifically, the initial values A and B of the NH ₃ adsorption amount are based on various conditions such as the volume of the reactor 12 and the adsorber 13, the amount of heat to be generated in the reactor 12, the NH ₃ filling pressure, the filling time, and the like. Is set. The NH ₃ adsorption amount of the adsorber 13 when the NH ₃ recovery rate of the adsorber 13 is 0% is required to keep the pressure in the adsorber 13 at a predetermined pressure.

However, when filling the adsorber 13 with a gaseous reaction medium such as NH _{3 at} a high pressure, NH ₃ sealed in the adsorber 13 is different from a liquid reaction medium such as water. The amount may vary from product to product. For this reason, the actual NH ₃ adsorption amount of the adsorber 13 in each of the state where the NH ₃ recovery rate of the adsorber 13 is 0% and the state of 100% is the state where the NH ₃ recovery rate of the adsorber 13 is 0%. The NH ₃ adsorption amount of the adsorber 13 in each of the 100% states deviates from the initial value. Therefore, the controller 24 corrects the NH ₃ adsorption amount of the adsorber 13 when the NH ₃ recovery rate of the adsorber 13 is 0% and 100%, respectively.

FIG. 4 is a flowchart showing details of a processing procedure executed by the controller 24. This process is executed when the catalyst is warmed up when the exhaust gas temperature is low, such as when the engine 2 is started. Note that the valve 15 is closed at the start of execution of this process. Further, the NH ₃ recovery rate of the adsorber 13 is 100%.

In FIG. 4, the controller 24 first determines whether or not the engine 2 has been started (step S101). Whether or not the engine 2 has been started is determined, for example, based on whether or not an ignition switch is turned on.

Subsequently, if the controller 24 determines that the exhaust gas temperature is low when the engine 2 is started, the controller 24 controls to open the valve 15 in order to warm the exhaust gas (step S102). When the valve 15 is opened, NH ₃ is supplied from the adsorber 13 to the reactor 12 due to the pressure difference between the adsorber 13 and the reactor 12, as shown in FIG. The reaction material 17 in the reactor 12 and NH ₃ react chemically to generate heat. At this time, NH ₃ moves from the adsorber 13 to the reactor 12 with the passage of time, and the amount of NH ₃ adsorption in the adsorber 13 gradually decreases, so the pressure in the adsorber 13 gradually decreases. When a predetermined time elapses, the pressure fluctuation per unit time in the adsorber 13 decreases, and the pressure in the adsorber 13 becomes a substantially constant value.

At this time, the controller 24 obtains the pressure change amount per unit time in the adsorber 13 based on the detection value of the pressure sensor 23, and the threshold value P in which the pressure change amount per unit time in the adsorber 13 is determined in advance. It is determined whether or not (first predetermined value) or less (step S103). When the controller 24 determines that the pressure change amount per unit time in the adsorber 13 is equal to or less than the threshold value P, the NH ₃ adsorption amount of the adsorber 13 based on the detection values of the temperature sensor 22 and the pressure sensor 23. Is estimated as the first update value (step S104).

The estimated value of the NH ₃ adsorption amount is estimated using the NH ₃ saturated vapor pressure characteristic shown in FIG. 6A and the NH ₃ adsorption characteristic shown in FIG. The NH ₃ saturated vapor pressure characteristic shown in FIG. 6A is a graph showing the relationship between the temperature of the adsorber 13 and the NH ₃ saturated vapor pressure, and the NH ₃ saturated vapor pressure increases as the temperature of the adsorber 13 increases. It has the characteristic that becomes high. The NH ₃ adsorption characteristic shown in FIG. 6B is a graph showing the relationship between the relative pressure and the NH ₃ adsorption amount of the adsorber 13, and the NH ₃ adsorption amount of the adsorber 13 increases as the relative pressure increases. It has the characteristic which becomes. The relative pressure is a ratio (P / P _sat ) between the NH ₃ saturated vapor pressure P _sat and the pressure P in the adsorber 13.

The controller 24 first obtains the NH ₃ saturated vapor pressure P _sat corresponding to the temperature T of the adsorber 13 detected by the temperature sensor 22 from the NH ₃ saturated vapor pressure characteristic. Then, the controller 24 calculates a relative pressure that is a ratio between the NH ₃ saturated vapor pressure P _sat and the pressure P of the adsorber 13 detected by the pressure sensor 23. Then, the controller 24 obtains the NH ₃ adsorption amount S _nh3 corresponding to the relative pressure from the NH ₃ adsorption characteristics. Thereby, the NH ₃ adsorption amount can be easily estimated.

Subsequently, the controller 24 uses the NH ₃ adsorption amount of the adsorber 13 estimated when the pressure change amount per unit time in the adsorber 13 is equal to or less than the threshold value P, and the NH ₃ recovery rate of the adsorber 13 is 0. % Is set to the NH ₃ adsorption amount of the adsorber 13 (step S105).

Specifically, as shown in FIG. 7A, the NH ₃ adsorption amount (first value) of the adsorber 13 estimated when the pressure change amount per unit time in the adsorber 13 becomes equal to or less than the threshold value P. When the updated value) is A + α, the NH ₃ adsorption amount of the adsorber 13 in a state where the NH ₃ recovery rate of the adsorber 13 is 0% is set when the adsorber 13 is charged with NH ₃ . The initial value A is corrected to the first update value A + α. Therefore, when the NH ₃ recovery rate of the adsorber 13 is 0%, the NH ₃ adsorption amount of the adsorber 13 is A + α.

When the exothermic reaction is completed, the controller 24 controls to close the valve 15 (step S106). Thereafter, the controller 24 estimates the temperature of the reactor 12 based on the detected value of the temperature sensor 21, and determines whether or not the temperature of the reactor 12 is equal to or higher than the reproducible temperature (step S107).

When the controller 24 determines that the temperature of the reactor 12 is equal to or higher than the regenerative temperature, the controller 24 controls to open the valve 15 in order to recover NH ₃ (step S108). When the valve 15 is opened, NH ₃ is supplied from the reactor 12 to the adsorber 13 as shown in FIG. 5B, and NH ₃ is recovered in the adsorber 13 as described above. At this time, with the passage of time, NH ₃ moves from the reactor 12 to the adsorber 13 and the amount of NH ₃ adsorbed in the adsorber 13 gradually increases, so that the pressure in the adsorber 13 gradually increases. When a predetermined time elapses, the pressure fluctuation per unit time in the adsorber 13 decreases, and the pressure in the adsorber 13 becomes a substantially constant value.

At this time, the controller 24 obtains the pressure change amount per unit time in the adsorber 13 based on the detection value of the pressure sensor 23, and the threshold value Q in which the pressure change amount per unit time in the adsorber 13 is determined in advance. It is determined whether or not (second predetermined value) or less (step S109). The threshold value Q used here may be the same value as or different from the threshold value P used in step S103.

When the controller 24 determines that the pressure change amount per unit time in the adsorber 13 has become the threshold value Q or less, the NH ₃ adsorption of the adsorber 13 based on the detected values of the temperature sensor 22 and the pressure sensor 23. The amount is estimated as the second update value (step S110). The estimation of the NH ₃ adsorption amount is performed by the same method as in the above step S104.

Then, the controller 24 determines the NH ₃ adsorption amount of the adsorber 13 estimated when the pressure change amount per unit time in the adsorber 13 is equal to or less than the threshold value Q, and the NH ₃ recovery rate of the adsorber 13 is 100%. The NH ₃ adsorption amount of the adsorber 13 in this state is set (step S111).

Specifically, as shown in FIG. 7B, the NH ₃ adsorption amount (second value) of the adsorber 13 estimated when the pressure change amount per unit time in the adsorber 13 becomes equal to or less than the threshold value Q. When the renewal value is B + β, the NH ₃ adsorption amount of the adsorber 13 in a state where the NH ₃ recovery rate of the adsorber 13 is 100% is set to the second value described above when the adsorber 13 is charged with NH ₃ . The initial value B is corrected to the second updated value B + β. Therefore, when the NH ₃ recovery rate of the adsorber 13 is 100%, the NH ₃ adsorption amount of the adsorber 13 is B + β.

In the above, when NH ₃ is supplied from the adsorber 13 to the reactor 12, the controller 24 obtains the pressure change amount per unit time in the adsorber 13 based on the pressure in the adsorber 13, and the adsorber 13. The NH ₃ adsorption amount of the adsorber 13 estimated using the pressure in the adsorber 13 when the amount of pressure change per unit time becomes equal to or less than the first predetermined value is used as the NH ₃ recovery rate of the adsorber 13. There a first setting unit that sets the adsorbed NH ₃ amount of adsorber 13 at 0% state, when the NH ₃ is supplied to the adsorber 13 from the reactor 12, the adsorber on the basis of the pressure within the adsorber 13 The amount of pressure change per unit time in 13 is obtained, and the adsorber estimated using the pressure in the adsorber 13 when the amount of pressure change per unit time in the adsorber 13 becomes equal to or less than the second predetermined value. the NH ₃ adsorption of 13, NH ₃ recovery adsorbers 13 Has a second setting unit that sets the NH ₃ adsorption amount of the adsorber 13 in a state of 100%.

By the way, there is a case where the NH ₃ recovery operation is terminated when the NH ₃ recovery rate of the adsorber 13 reaches a predetermined value or more (for example, 80% or more), and is controlled to prepare for the next heat generation operation. Then, the NH ₃ adsorption amount of the adsorber 13 when the NH ₃ recovery rate of the adsorber 13 is 100% is as shown in FIG. 7B when the NH ₃ recovery rate is actually 100%. When the amount is set lower than the adsorption amount (second initial value B), even if the NH ₃ recovery rate is 80% or more, a sufficient amount of NH ₃ is actually recovered in the adsorber 13. Will not be. Therefore, when NH ₃ is subsequently supplied from the adsorber 13 to the reactor 12 to cause a chemical reaction between the reactant 17 and NH ₃ , a sufficient amount of heat is not generated from the reactant 17, resulting in exhaust gas. Gas heating will be insufficient. Further, the adsorbed NH ₃ amount of adsorber 13 in a state NH ₃ recovery of 0% adsorbers 13, as shown in FIG. 7 (a), when the actual NH ₃ recovery ratio was 0% FIG. 7B shows the NH ₃ adsorption amount of the adsorber 13 when the NH ₃ recovery rate of the adsorber 13 is 100% when set to an amount lower than the adsorption amount (first initial value A). As shown in FIG. 2, when the amount of adsorption is set lower than the amount of adsorption when the NH ₃ recovery rate is actually 100% (second initial value B), there is a deviation from the actual amount of adsorption of NH _3. When the failure detection of the NH3 supply system composed of the reactor 12, the adsorber 13, the NH3 supply pipe 14, and the valve 15 is performed, it becomes a cause of erroneous detection.

On the other hand, in this embodiment, when NH ₃ is supplied from the adsorber 13 to the reactor 12, the pressure in the adsorber 13 when the pressure change amount per unit time in the adsorber 13 becomes equal to or less than the threshold value P. the NH ₃ adsorption amount of adsorber 13, which is estimated using the sets to adsorbed NH ₃ amount of adsorber 13 in a state NH ₃ recovery of 0% adsorber 13. Thereby, the NH ₃ adsorption amount of the adsorber 13 when the NH ₃ recovery rate of the adsorber 13 is 0% can be accurately recognized. On the other hand, when NH ₃ was supplied from the reactor 12 to the adsorber 13, the pressure change amount per unit time in the adsorber 13 was estimated using the pressure in the adsorber 13 when the pressure change amount per unit time was equal to or less than the threshold value Q. the NH ₃ adsorption amount of adsorber 13 is set to adsorbed NH ₃ amount of adsorber 13 in a state NH ₃ recovery is 100% of the adsorber 13. Thereby, the NH ₃ adsorption amount of the adsorber 13 when the NH ₃ recovery rate of the adsorber 13 is 100% can be accurately recognized.

Further, when the pressure change amount per unit time in the adsorber 13 becomes equal to or less than the threshold value P, the NH ₃ adsorption amount of the adsorber 13 when the NH ₃ recovery rate of the adsorber 13 is 0% is changed to the adsorber 13. The first initial value A set at the time of NH ₃ filling is corrected to the NH ₃ adsorption amount (first updated value A + α) of the adsorber 13 estimated using the pressure in the adsorber 13, and the inside of the adsorber 13 is corrected. When the amount of change in pressure per unit time becomes equal to or less than the threshold value Q, the NH ₃ adsorption amount of the adsorber 13 when the NH ₃ recovery rate of the adsorber 13 is 100% is set when the adsorber 13 is charged with NH _3. The second initial value B is corrected to the NH ₃ adsorption amount (second updated value B + β) of the adsorber 13 estimated using the pressure in the adsorber 13. For this reason, even if the initial values A and B set when the adsorber 13 is filled with NH ₃ deviate from the updated values A + α and B + β estimated using the pressure in the adsorber 13, the NH of the adsorber 13 _{3 The} amount of NH ₃ adsorbed by the adsorber 13 in each of the recovery rate of 0% and 100% can be accurately recognized.

Therefore, when NH ₃ is recovered, a sufficient amount of NH ₃ is recovered in the adsorber 13. Therefore, a sufficient amount of heat can be generated from the reactant 17 when NH ₃ is supplied from the adsorber 13 to the reactor 12 to cause the reactant 17 and NH ₃ to chemically react. Thereby, the heating (warming-up) performance of the exhaust gas can be ensured. Further, the detection accuracy can be improved when the failure detection of the NH ₃ supply system is performed.

In the present embodiment, the example in which the update value is larger than the initial value is shown, but the update value may be smaller than the initial value. In this case, for example, the first initial value A is corrected as the first update value A-α, or the second initial value B is corrected as the second update value B-β.

As mentioned above, although embodiment of this invention has been described, this invention is not limited to the said embodiment. For example, in the above embodiment, the temperature of the adsorber 13 is directly detected by the temperature sensor 22 connected to the adsorber 13, but the present invention is not limited to this, and the detection value of the temperature sensor connected to the reactor 12 is used. It may be used to estimate the temperature of the adsorber 13. Further, the pressure in the adsorber 13 is directly detected by the pressure sensor 23 connected to the adsorber 13, but the present invention is not limited to this, and the adsorber is detected using the detection value of the pressure sensor connected to the reactor 12. The pressure in 13 may be estimated.

Moreover, in the said embodiment, the temperature of the exhaust gas which flows through the part upstream from the heat exchanger 3 in the exhaust passage 8 is detected by the temperature sensor 21, and the temperature of the reactor 12 is estimated using the detected value. However, the temperature sensor used for estimating the temperature of the reactor 12 is not particularly limited thereto. For example, the temperature of the exhaust gas flowing through the portion of the exhaust passage 8 downstream of the heat exchanger 3 may be detected by a temperature sensor, and the temperature of the reactor 12 may be estimated using the detected value. If the temperature sensor can be attached to the reactor 12, the temperature of the reactor 12 itself may be directly detected by the temperature sensor.

In the above embodiment, NH ₃ and the reaction material 17 represented by the composition formula MXa are chemically reacted to generate heat. However, the gaseous reaction medium is not particularly limited to NH ₃ , for example, CO ₂ or the like may be used. In this case, the reaction material that chemically reacts with CO ₂ includes MgO, CaO, BaO, Ca (OH) ₂ , Mg (OH) ₂ , Fe (OH) ₂ , Fe (OH) ₃ , FeO, and Fe ₂ O _3. or it can be used _Fe 3 _{O 4} or the like.

Furthermore, in the said embodiment, although the reactor 12 is arrange | positioned around the outer cylinder 9 of the heat exchanger 3, this invention is an inside of an exhaust pipe, and the reactor and heat exchanger which have a reaction material alternately The present invention can also be applied to a chemical heat storage device that is laminated.

In the chemical heat storage device 11 of the above embodiment, the exhaust gas discharged from the diesel engine 2 is heated (warmed up). However, the present invention is not limited to this, and the chemical heat storage for heating the exhaust gas discharged from the gasoline engine is used. The present invention may be applied to an apparatus or the like, and the present invention may be applied to a chemical heat storage device that heats an exhaust gas purifying catalyst, a heat exchanger, or other engine components. In addition to the exhaust gas, the present invention may be applied to a chemical heat storage device that heats a gaseous or liquid fluid (for example, oil, water, air, water vapor). Moreover, you may apply the chemical heat storage apparatus of this invention to a garbage incineration factory, a power plant, various plant factories, etc. besides an engine.

11 ... chemical heat storage device, 12 ... reactor, 13 ... adsorber, 14 ... NH ₃ supply pipe, 17 ... reaction member, 20 ... adsorbent, 22 ... temperature sensor (adsorber temperature acquisition unit), 23 ... Pressure sensor ( Adsorber pressure acquisition unit), 24... Controller (first setting unit, second setting unit).

Claims (3)

1. An adsorber having an adsorbent capable of adsorbing and desorbing the reaction medium;
   A reactor having a reaction material which generates heat by a chemical reaction with the reaction medium when the reaction medium is supplied, and absorbs heat to desorb the reaction medium when heated;
   A supply pipe connecting the adsorber and the reactor so that the reaction medium can flow between the adsorber and the reactor;
   An adsorber pressure acquisition unit for acquiring the pressure in the adsorber;
   When the reaction medium is supplied from the adsorber to the reactor, the amount of pressure change per unit time in the adsorber is obtained based on the pressure in the adsorber, and per unit time in the adsorber. The amount of adsorption of the reaction medium in the adsorber estimated using the pressure in the adsorber when the pressure change amount is equal to or less than the first predetermined value is obtained when the reaction medium recovery rate of the adsorber is 0%. A first setting unit for setting a reaction medium adsorption amount of the adsorber;
   When the reaction medium is supplied from the reactor to the adsorber, the amount of pressure change per unit time in the adsorber is obtained based on the pressure in the adsorber, and per unit time in the adsorber. The adsorbent reaction medium adsorption amount estimated using the pressure in the adsorber when the pressure change amount is equal to or less than the second predetermined value is obtained when the adsorber reaction medium recovery rate is 100%. A chemical heat storage device comprising: a second setting unit configured to set a reaction medium adsorption amount of the adsorber.
2. The first setting unit sets a reaction medium adsorption amount of the adsorber using a pressure in the adsorber when a pressure change amount per unit time in the adsorber becomes equal to or less than the first predetermined value. Estimated as one updated value, and the amount of adsorption of the reaction medium in the adsorber in the state where the reaction medium recovery rate of the adsorber is 0% is determined from the first initial value set when the adsorber is filled with the reaction medium. Correcting to the first update value,
   The second setting unit sets a reaction medium adsorption amount of the adsorber by using a pressure in the adsorber when a pressure change amount per unit time in the adsorber becomes the second predetermined value or less. 2 is estimated as an updated value, and the adsorption amount of the reaction medium in the adsorber in a state where the reaction medium recovery rate of the adsorber is 100% is determined from the second initial value set when the adsorber is filled with the reaction medium. The chemical heat storage device according to claim 1, wherein the chemical heat storage device is corrected to the second update value.
3. An adsorber temperature acquisition unit for acquiring the temperature of the adsorber;
   The first setting unit and the second setting unit estimate a reaction medium adsorption amount of the adsorber based on a pressure in the adsorber and a temperature of the adsorber. The chemical heat storage device described.

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