CN112649590A

CN112649590A - Similar simulation experiment equipment

Info

Publication number: CN112649590A
Application number: CN202011530231.5A
Authority: CN
Inventors: 王平; 胡彦; 程爱平; 郑先伟; 俞栋华; 胡倡瑞; 张威威; 张彦文
Original assignee: Wuhan University of Science and Engineering WUSE
Current assignee: Wuhan University of Science and Engineering WUSE
Priority date: 2020-12-22
Filing date: 2020-12-22
Publication date: 2021-04-13
Anticipated expiration: 2040-12-22
Also published as: CN112649590B

Abstract

The invention discloses a similar simulation experiment device, and belongs to the technical field of mine similar simulation experiments. The analog simulation experiment equipment comprises: the device comprises a constant temperature box, an experiment frame, a bottom plate, a first baffle and a plurality of baffle assemblies; the experiment frame is fixedly arranged on the bottom plate; the incubator can be arranged on the bottom plate in a sliding manner, and the experiment frame can be arranged in the incubator; the first baffle is detachably arranged on the first side of the experiment frame, the first baffle component in the plurality of baffle components is slidably arranged at the bottom of the second side of the experiment frame, every two adjacent baffle components in the plurality of baffle components are slidably arranged between the baffle components, and the first side of the experiment frame is opposite to the second side of the experiment frame. The simulation modeling experiment equipment provided by the invention reduces the influence on other places of the model during model excavation, so that the simulation modeling experiment result is more accurate.

Description

Similar simulation experiment equipment

Technical Field

The invention relates to the technical field of mine analog simulation experiments, in particular to analog simulation experiment equipment.

Background

The analog simulation research is an important scientific research means, a model similar to a prototype is manufactured in a laboratory according to an analog principle, mechanical parameters and a distribution rule in the model are observed by means of a resistance strain gauge, and a mechanical phenomenon possibly occurring in the prototype and a rule of rock mass pressure distribution are deduced by using a result of the research on the model, so that the practical problem in rock mass engineering production is solved.

But at model maintenance and experiment excavation in-process, if there is the bulk solid in the model, the bulk solid can the landing during the excavation, if shelter from temporarily, then make the experiment extremely inconvenient, finally lead to the experimental result to appear the deviation.

Disclosure of Invention

The invention provides a similar simulation experiment device, which solves or partially solves the technical problems that in the model maintenance and experiment excavation process of similar simulation research in the prior art, if discrete bodies exist in a model, the discrete bodies can slide off in the excavation process, and if the discrete bodies are temporarily shielded, the experiment is extremely inconvenient, and finally the experiment result is deviated.

In order to solve the above technical problems, the present invention provides a similar simulation experiment apparatus comprising: the device comprises a constant temperature box, an experiment frame, a bottom plate, a first baffle and a plurality of baffle assemblies; the experiment frame is fixedly arranged on the bottom plate; the incubator can be arranged on the bottom plate in a sliding manner, and the experiment frame can be arranged in the incubator; the first baffle is detachably arranged on the first side of the experiment frame, the first baffle component in the plurality of baffle components is slidably arranged at the bottom of the second side of the experiment frame, every two adjacent baffle components in the plurality of baffle components are slidably arranged between the baffle components, and the first side of the experiment frame is opposite to the second side of the experiment frame.

Furthermore, a first end of the first side of the experiment frame is provided with a first through groove, and a second end of the first side of the experiment frame is provided with a second through groove; the first baffle passes through the first through groove and enters the second through groove.

Furthermore, a first guide rail is arranged at the top of the first side of the experiment frame, and a second guide rail is arranged at the bottom of the second side of the experiment frame; the top of the first baffle is slidably disposed in the first guide rail, and the bottom of the first baffle is slidably disposed in the second guide rail.

Furthermore, a first end of a second side of the experiment frame is provided with a plurality of third through grooves, a second end of the second side of the experiment frame is provided with a fourth through groove, and the plurality of third through grooves correspond to the plurality of fourth through grooves one to one; the baffle assemblies correspond to the third through grooves one by one, and the baffle assemblies penetrate through the corresponding third through grooves to enter the fourth through grooves.

Further, the baffle plate assembly includes: a second baffle and a third baffle; the end face, facing the third baffle, of the second baffle is provided with a first groove, the end face, facing the third baffle, of the third baffle is provided with a first protrusion, and the first protrusion can be embedded into the first groove.

Furthermore, second grooves are formed in the tops of the baffle plate assemblies, and first sliding blocks are arranged at the bottoms of the baffle plate assemblies; the first sliding block of a first baffle assembly in the baffle assemblies is slidably arranged at the bottom of the second side of the experiment rack; the first sliding block of each two adjacent baffle plate assemblies in one baffle plate assembly is slidably arranged in the second groove of the other baffle plate assembly.

Further, the oven includes: a box body and heat insulation glass; the box body is arranged on the bottom plate in a sliding manner; the side of box has seted up the opening, heat insulating glass can set up with convertible the opening part.

Further, the simulation modeling experiment apparatus further includes: a control device; the control device includes: the controller, the temperature control assembly and the humidity control assembly; the controller is connected with the temperature control assembly, and the temperature control assembly is arranged in the constant temperature box; the controller is connected with the humidity control assembly, and the humidity control assembly is arranged in the constant temperature box.

Further, the temperature control assembly comprises: a thermistor and a heater; the thermistor and the heater are both fixedly arranged in the constant temperature box; the thermistor and the heater are both connected with the controller; the thermistor sends a temperature signal to the controller, and the controller sends a heating signal to the heater according to the temperature signal.

Further, the temperature control assembly comprises: a humidity sensitive resistor and a humidifier; the humidity sensitive resistor and the humidifier are both fixedly arranged in the constant temperature box; the humidity sensitive resistor and the humidifier are both connected with the controller; the humidity-sensitive resistor sends a humidity signal to the controller, and the controller sends a humidification signal to the humidifier according to the humidity signal.

One or more technical solutions provided in the embodiments of the present application have at least the following technical effects or advantages:

because the experiment frame is fixedly arranged on the bottom plate, the incubator is arranged on the bottom plate in a sliding manner, the experiment frame can be arranged in the incubator, the first baffle plate is arranged on the first side of the experiment frame in a detachable manner, the first baffle plate assembly in the plurality of baffle plate assemblies is arranged at the bottom of the second side of the experiment frame in a sliding manner, every two adjacent baffle plate assemblies in the plurality of baffle plate assemblies are arranged in a sliding manner, the first side of the experiment frame is opposite to the second side of the experiment frame, therefore, the incubator slides on the bottom plate to expose the experiment frame, the first baffle plate is arranged on the first side of the experiment frame, the first baffle plate assembly in the plurality of baffle plate assemblies is arranged at the bottom of the second side of the experiment frame, the baffle plate assemblies are arranged layer by layer according to the height of the model, the number of the baffle plate assemblies meeting the requirements is selected, and a part of the model is manufactured in the experiment frame after, done until the model, then, the thermostated container slides on the bottom plate, make the experiment frame get into the thermostated container in, maintain the model, when the model maintenance is accomplished, the thermostated container slides on the bottom plate, make the experiment frame expose, when the excavation of simulation mining, when excavating the model in a certain place, operate the baffle subassembly of this department, the baffle subassembly of this department slides on adjacent baffle subassembly, make the model in a certain place expose, excavate, and the other parts of model are not influenced, there is not the bulk material landing, also not shelter from temporarily, the experiment is convenient, make the simulation modeling experiment result more accurate.

Drawings

FIG. 1 is a front view of a simulation modeling experiment apparatus according to an embodiment of the present invention;

FIG. 2 is a side view of the similar simulation test apparatus of FIG. 1;

FIG. 3 is a top view of the similar simulation test apparatus of FIG. 1;

fig. 4 is a schematic structural diagram of a second baffle plate of the similar simulation experiment device in fig. 1.

Detailed Description

Referring to fig. 1 to 3, a simulation modeling experiment apparatus provided in an embodiment of the present invention includes: the device comprises a thermostat 1, an experiment frame 2, a bottom plate 3, a first baffle 4 and a plurality of baffle assemblies 5.

The experiment frame 2 is fixedly arranged on the bottom plate 3.

The incubator 1 is slidably disposed on the base plate 3, and the experimental rack 2 is disposed in the incubator 1.

First baffle 4 sets up in the first side of experiment frame 2 detachablely, and the first baffle subassembly slidable sets up in the bottom of the second side of experiment frame 2 in a plurality of baffle subassemblies 5, and slidable sets up between every two adjacent baffle subassemblies in a plurality of baffle subassemblies 5, and the first side of experiment frame 2 is relative with the second side of experiment frame 2.

In the embodiment of the application, because the experiment frame 2 is fixedly arranged on the bottom plate 3, the incubator 1 is arranged on the bottom plate 3 in a sliding manner, the experiment frame 2 can be arranged in the incubator 1, the first baffle plate 4 is arranged on the first side of the experiment frame 2 in a detachable manner, the first baffle plate assembly in the baffle plate assemblies 5 is arranged at the bottom of the second side of the experiment frame 2 in a sliding manner, every two adjacent baffle plate assemblies in the baffle plate assemblies 5 are arranged in a sliding manner, the first side of the experiment frame 2 is opposite to the second side of the experiment frame 2, therefore, the incubator 1 slides on the bottom plate 3 to expose the experiment frame 2, the first baffle plate 4 is arranged on the first side of the experiment frame 2, the first baffle plate assembly in the baffle plate assemblies 5 is arranged at the bottom of the second side of the experiment frame 2, the number of the baffle plate assemblies 5 meeting the requirement is selected according to the height of the model, install baffle subassembly 5 layer by layer, every one deck baffle subassembly 5 of having installed, then make some models in experiment frame 2, do until the model, then, thermostated container 1 slides on bottom plate 3, make experiment frame 2 get into thermostated container 1 in, maintain the model, when the model maintenance is accomplished, thermostated container 1 slides on bottom plate 3, make experiment frame 2 expose, when the simulation mining excavation, when excavating some local model, operate the baffle subassembly 5 of this department, the baffle subassembly 5 of this department slides on adjacent baffle subassembly, make some local model expose, excavate, and the other parts of model are not influenced, do not have the bulk material landing, also do not shelter from temporarily, it is convenient to experiment, make similar simulation experiment result more accurate.

In the present embodiment, the third side of the experiment rack 2 and the fourth side of the experiment rack 2 are both closed, and a closed space for accommodating the model can be formed by the third side of the experiment rack 2 and the fourth side of the experiment rack 2, and the first baffle 4 and the baffle assembly 5.

Specifically, the first end of the first side of experiment frame 2 has been seted up first logical groove, and the second end of the first side of experiment frame 2 has been seted up the second and has been led to the groove.

First baffle 4 passes first logical inslot entering second for the first side of shutoff experiment frame 2.

In this embodiment, first logical groove and second lead to groove department and all be provided with clamp bolt 6, when first baffle 4 passed first logical groove and gets into the second and lead to the groove, locking clamp bolt 6 guarantees first baffle 5 and experiment frame 2 fastening connection, when the experiment finishes, can loosen clamp bolt 6, leads to the groove by the second with first baffle 5 and first logical inslot takes out, is convenient for take out the model that will accomplish the experiment.

Specifically, a first guide rail is arranged at the top of the first side of the experiment frame 2, and a second guide rail is arranged at the bottom of the second side of the experiment frame 2; the top of first baffle 4 can be established in first guide rail slidablely, and the bottom of first baffle 4 can be set up in the second guide rail slidablely, is convenient for first baffle 4 to get into the second and leads to the groove or leave logical groove, simultaneously, can carry on spacingly to the motion of first baffle 4.

Specifically, a plurality of third through grooves have been seted up to the first end of the second side of experiment frame 2, and the fourth through groove has been seted up to the second end of the second side of experiment frame 2, and a plurality of third through grooves and a plurality of fourth through groove one-to-one.

The baffle plate assemblies 5 correspond to the third through grooves one by one, and the baffle plate assemblies 5 penetrate through the corresponding third through grooves to enter the fourth through grooves.

When a model is to be prepared, the number of baffle assemblies 5 meeting requirements is selected according to the height of the model, the baffle assemblies 5 are installed layer by layer, the baffle assemblies 5 penetrate through the corresponding third through grooves to enter the fourth through grooves, and when one layer of baffle assembly 5 is installed, a part of the model is manufactured in the experiment frame 2 until the model is finished.

Referring to fig. 4, the baffle plate assembly 5 includes: a second baffle 5-1 and a third baffle 5-2.

The end face, facing the third baffle 5-2, of the second baffle 5-1 is provided with a first groove, the end face, facing the second baffle 5-1, of the third baffle 5-2 is provided with a first protrusion, and the first protrusion can be embedded into the first groove.

When a model is to be prepared, the number of baffle assemblies 5 meeting requirements is selected according to the height of the model, the baffle assemblies 5 are installed layer by layer, a second baffle 5-1 of each baffle assembly 5 penetrates through the corresponding third through groove to slide on the adjacent baffle assembly, and a third baffle 5-2 of each baffle assembly 5 penetrates through the corresponding fourth through groove to slide on the adjacent baffle assembly until the first protrusion is embedded into the first groove, so that the model is supported. When mining excavation is simulated and a model in a certain place is excavated, the baffle plate assembly 5 in the place is operated, the second baffle plate 5-1 of the baffle plate assembly 5 in the place slides on the adjacent baffle plate assembly, the third baffle plate 5-2 of the baffle plate assembly 5 in the place slides on the adjacent baffle plate assembly, so that the first protrusion leaves the first groove, the second baffle plate 5-1 moves towards the first side of the experiment frame 2, and the third baffle plate 5-2 moves towards the second side of the experiment frame 2, or the first baffle plate 5-1 or the second baffle plate 5-2 is directly pushed, so that the second baffle plate 5-1 pushes the third baffle plate 5-2 to move towards the second side of the experiment frame 2 or the third baffle plate 5-2 pushes the second baffle plate 5-1 to move towards the first side of the experiment frame 2, so that the model in a certain place is exposed and excavated, and other parts of the model are not affected, the device has the advantages of no dispersion slip and no temporary shielding, is convenient to test, and enables the result of the similar simulation test to be more accurate.

The first baffle 4, the second baffle 5-1 and the third baffle 5-2 can be made of wood.

Specifically, the top of each baffle plate assembly 5 is provided with a second groove 5-11, and the bottom of each baffle plate assembly 5 is provided with a first sliding block 5-12.

The first slide 5-12 of a first one of the plurality of shutter assemblies 5 is slidably disposed at the bottom of the second side of the experimental rack 2. In this embodiment, the bottom of the second side of the experimental frame 2 is fixedly provided with a third guide rail, which facilitates the sliding of the first sliding blocks 5-12 of the first baffle assembly of the plurality of baffle assemblies 5, and simultaneously limits the sliding of the first baffle assembly of the plurality of baffle assemblies 5.

The first sliding block 5-12 of one baffle assembly of every two adjacent baffle assemblies is slidably arranged in the second groove 5-11 of the other baffle assembly, so that the sliding between every two adjacent baffle assemblies of the plurality of baffle assemblies 5 is facilitated, and meanwhile, the sliding of the baffle assemblies 5 can be limited.

Specifically, oven 1 comprises: a box body 1-1 and heat insulation glass 1-2.

The case 1-1 is slidably disposed on the base plate 3. In this embodiment, a fourth guide rail 7 is fixedly disposed on the bottom plate 3, a second slider is fixedly disposed at the bottom of the box body 1-1, and the second slider is slidably disposed in the fourth guide rail 7, so as to facilitate the sliding of the box body 1-1 and limit the sliding of the box body 1-1.

An opening is arranged on the side part of the box body 1-1, and the heat insulation glass 1-2 is arranged at the opening in a turnover mode. In the embodiment, a first side of the heat insulation glass 1-2 is connected with the box body 1-1 through a hinge, a second side of the heat insulation glass 1-2 is connected with the box body 1-1 through a telescopic cylinder 8, wherein a telescopic end of the telescopic cylinder 8 is hinged with the heat insulation glass 1-2, and a fixed end of the telescopic cylinder 8 is hinged with the box body 1-1.

When the experiment frame 2 needs to be exposed, the telescopic cylinder 8 is started, the telescopic end of the telescopic cylinder 8 extends to drive the heat insulation glass 1-2 to turn over, the opening is opened, and then the box body 1-1 slides on the fourth guide rail 7 to expose the experiment frame 2. When the model is maintained, the box body 1-1 slides on the fourth guide rail 7, the experiment frame 2 enters the box body 1-1, the telescopic cylinder 8 is started, the telescopic end of the telescopic cylinder 8 retracts, the heat insulation glass 1-2 is driven to turn over, the opening is sealed, and heat insulation is carried out.

Meanwhile, sealing strips are arranged at the joints of the peripheral surfaces of the heat insulation glass 1-2 and the box body 1-1, so that the sealing effect of the heat insulation glass 1-1 is ensured.

Specifically, the simulation modeling experiment apparatus further includes: and a control device 9.

The control device 9 includes: a controller 9-1, a temperature control component 9-2 and a humidity control component 9-3.

The controller 9-1 is connected with the temperature control assembly 9-2, and the temperature control assembly 9-2 is arranged in the incubator 1.

The controller 9-1 is connected with the humidity control assembly 9-3, and the humidity control assembly 9-3 is arranged in the incubator 1.

The temperature control assembly 9-2 comprises: thermistors 9-21 and heaters 9-22.

The thermistors 9-21 and the heaters 9-22 are all fixedly arranged in the incubator 1.

The thermistors 9-21 and the heaters 9-22 are connected with the controller 9-1.

Wherein, the thermistor 9-21 sends a temperature signal to the controller 9-1, and the controller 9-1 sends a heating signal to the heater 9-22 according to the temperature signal.

The temperature control assembly 9-3 comprises: a humidity sensitive resistor 9-31 and a humidifier 9-32.

The humidity sensitive resistor 9-3 and the humidifier 9-32 are both fixedly arranged in the constant temperature box 1.

The humidity sensitive resistor 9-31 and the humidifier 9-32 are both connected with the controller 9-1.

The humidity-sensitive resistor 9-31 sends a humidity signal to the controller 9-1, and the controller 9-1 sends a humidification signal to the humidifier 9-32 according to the humidity signal.

When the model is maintained, the temperature in the constant temperature box 1 is sensed by the thermistors 9-21, a temperature signal is sent to the controller 9-1, the controller 9-1 sends a heating signal to the heaters 9-22 according to the temperature signal to ensure that the temperature in the constant temperature box 1 is constant, the humidity in the constant temperature box 1 is sensed by the humidity-sensitive resistors 9-31 and sent to the controller 9-1, and the controller 9-1 sends a humidifying signal to the humidifier 9-32 according to the humidity signal to ensure that the humidity in the constant temperature box 1 is constant.

During the maintenance process of the model and when the data is measured after the model is excavated, the result is greatly influenced by the change of the temperature, and the model can be maintained in a constant-temperature and constant-humidity environment through the heaters 9-22 and the humidifiers 9-32; after the model is excavated, data can be observed under the conditions of constant temperature and constant humidity, so that the influence of environmental change on an experimental result is reduced as much as possible while the strength of the model reaches an ideal degree.

Wherein, the number of the thermistors 9-21, the heaters 9-22, the humidity-sensitive resistors 9-31 and the humidifiers 9-32 is multiple, and the thermistors, the heaters 9-22, the humidity-sensitive resistors 9-31 and the humidifiers 9-32 are arranged on the periphery of the inner wall of the box body 1-1 of the constant temperature box 1, so that the accuracy of a detection result is ensured, and the accuracy of a control result is also ensured.

In the present embodiment, the controller 9 is connected to the thermistors 9-21, the heaters 9-22, the humidity sensors 9-31, and the humidifiers 9-32 through cables, the cables are passed through the cabinet 1-1 of the oven 1, and hoses 9-4 for guiding the cables and protecting the cables are provided between the cabinet 1-1 of the oven 1 and the controller 9-1.

Further, the controller 9-1 is arranged on the operation table 10, and the resistance strain gauge is arranged on the operation table 10 and is connected with the controller 9-1, the thermistor 9-21 and the humidity sensor 9-31.

The temperature in the constant temperature box 1 is sensed by the thermistors 9-21, a temperature signal is sent to the controller 9-1 through the resistance strain gauge, the controller 9-1 sends a heating signal to the heaters 9-22 according to the temperature signal to ensure the temperature in the constant temperature box 1 to be constant, the humidity in the constant temperature box 1 is sensed by the humidity-sensitive resistors 9-31, a humidity signal is sent to the controller 9-1 through the resistance strain gauge, and the controller 9-1 sends a humidifying signal to the humidifiers 9-32 according to the humidity signal to ensure the humidity in the constant temperature box 1.

The length × width × height of the experimental frame 2 is 4000mm × 600mm × 1700mm, the length × width × height of the case 1-1 of the oven 1 is 5000mm × 1000mm × 2000mm, and the length × width × height of the operation table 10 is

＝900mm×500mm×1000mm。

Finally, it should be noted that the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting, and although the present invention has been described in detail with reference to examples, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the claims of the present invention.

Claims

1. A similar simulation experiment apparatus, comprising: the device comprises a constant temperature box, an experiment frame, a bottom plate, a first baffle and a plurality of baffle assemblies;

the experiment frame is fixedly arranged on the bottom plate;

the incubator can be arranged on the bottom plate in a sliding manner, and the experiment frame can be arranged in the incubator;

the first baffle is detachably arranged on the first side of the experiment frame, the first baffle component in the plurality of baffle components is slidably arranged at the bottom of the second side of the experiment frame, every two adjacent baffle components in the plurality of baffle components are slidably arranged between the baffle components, and the first side of the experiment frame is opposite to the second side of the experiment frame.

2. The analog simulation experiment apparatus of claim 1, wherein:

a first through groove is formed in the first end of the first side of the experiment frame, and a second through groove is formed in the second end of the first side of the experiment frame;

the first baffle passes through the first through groove and enters the second through groove.

3. The analog simulation experiment apparatus of claim 1, wherein:

the top of the first side of the experiment frame is provided with a first guide rail, and the bottom of the second side of the experiment frame is provided with a second guide rail;

the top of the first baffle is slidably disposed in the first guide rail, and the bottom of the first baffle is slidably disposed in the second guide rail.

4. The analog simulation experiment apparatus of claim 1, wherein:

the first end of the second side of the experiment frame is provided with a plurality of third through grooves, the second end of the second side of the experiment frame is provided with a fourth through groove, and the plurality of third through grooves correspond to the plurality of fourth through grooves one to one;

the baffle assemblies correspond to the third through grooves one by one, and the baffle assemblies penetrate through the corresponding third through grooves to enter the fourth through grooves.

5. The analog simulation experiment device of claim 1, wherein the baffle assembly comprises: a second baffle and a third baffle;

the end face, facing the third baffle, of the second baffle is provided with a first groove, the end face, facing the third baffle, of the third baffle is provided with a first protrusion, and the first protrusion can be embedded into the first groove.

6. The analog simulation experiment apparatus of claim 5, wherein:

the tops of the baffle plate assemblies are provided with second grooves, and the bottoms of the baffle plate assemblies are provided with first sliding blocks;

the first sliding block of a first baffle assembly in the baffle assemblies is slidably arranged at the bottom of the second side of the experiment rack;

the first sliding block of each two adjacent baffle plate assemblies in one baffle plate assembly is slidably arranged in the second groove of the other baffle plate assembly.

7. The analog simulation experiment apparatus of claim 1, wherein the incubator comprises: a box body and heat insulation glass;

the box body is arranged on the bottom plate in a sliding manner;

the side of box has seted up the opening, heat insulating glass can set up with convertible the opening part.

8. The semblance testing apparatus according to claim 1, further comprising: a control device;

the control device includes: the controller, the temperature control assembly and the humidity control assembly;

the controller is connected with the temperature control assembly, and the temperature control assembly is arranged in the constant temperature box;

the controller is connected with the humidity control assembly, and the humidity control assembly is arranged in the constant temperature box.

9. The analog simulation experiment device of claim 8, wherein the temperature control assembly comprises: a thermistor and a heater;

the thermistor and the heater are both fixedly arranged in the constant temperature box;

the thermistor and the heater are both connected with the controller;

the thermistor sends a temperature signal to the controller, and the controller sends a heating signal to the heater according to the temperature signal.

10. The analog simulation experiment device of claim 8, wherein the temperature control assembly comprises: a humidity sensitive resistor and a humidifier;

the humidity sensitive resistor and the humidifier are both fixedly arranged in the constant temperature box;

the humidity sensitive resistor and the humidifier are both connected with the controller;

the humidity-sensitive resistor sends a humidity signal to the controller, and the controller sends a humidification signal to the humidifier according to the humidity signal.