GR1010264B - Automatic boiler's temperature control system - Google Patents

Abstract

The present invention relates to an Electronic Parasite Monitoring System consisting of the electronic parasite detection sensor - or all that will be needed to cover a monitored area - the data collection and sending terminal and the data collection and processing software package being installed on the user's computer or in the cloud. After installation of the invented system, the user is in position to record all events related to the presence of parasites in real time and in his point of interest, in order to immediately address the problem.

Description

PATENT DESCRIPTION

AUTOMATIC BOILER TEMPERATURE CONTROL SYSTEM

The invention refers to a system of automatic temperature control of the hot water production of a boiler, by the method of turning the rotary temperature regulator of the boiler, by means of a servomotor whose axis of rotation depends on the external ambient temperature.

Corresponding boiler water temperature control systems in relation to the external ambient temperature, use the technique of mixing the supply water with the return water of the heating network through a three-way or four-way electric mixing valve, whose water mixing percentage depends on the external ambient temperature and the temperature of the water coming out of the three-way solenoid valve.

With this method, it becomes necessary to intervene in the installation of the heating network, both in the electrical circuit and in its hydraulic network, differentiating them from the initial application study.

Another method is the control of the water temperature of the boiler in relation to the external ambient temperature, through the start and stop of its operation by an electronic unit, which collects and processes the data from the sensors of the external ambient temperature and the temperature of the water of the heating network.

Through this method, it becomes necessary to intervene internally in the electrical circuit of the boiler, with the consequence of removing its operation from the original manufacturer and from any quality and safety certifications it carries.

The subject of the present invention is an automatic boiler temperature control system characterized by the fact that it has the ability to turn the rotary boiler temperature regulator, by means of a servomotor whose shaft rotation angle depends on the external ambient temperature.

The system consists of the main electronic control unit, a servo motor, the articulated arm of the servo motor, the drive commutator on the rotary boiler temperature controller, a temperature sensor mounted in a specially made perforated shell suitable for outdoor areas, two contact temperature sensors , one for reading the temperature through its contact, with the pipe of the mains water during extraction from the boiler and one for reading the temperature through its contact, with the pipe of the mains water when entering the boiler, as well as the magnetic support bases, one for the central control unit and one for the hinged support arm of the servomotor.

The purpose of the present invention is to achieve the automatic regulation of the boiler's hot water, without any necessary intervention in the hydraulic network and the electrical circuit inside the boiler. This is achieved by the process of turning the rotary temperature regulator of the boiler by means of a servomotor, whose angle of rotation of its axis depends on the external ambient temperature.

The new method applied by the invention, in contrast to the existing level, does not change the initial design and construction of the hot water heating network and also ensures that the boiler will not deviate in its operation from the specifications set by the manufacturer and the certifications quality and safety it brings.

Therefore, the possibility of the boiler exceeding the upper limit of water temperature production is zeroed out. In addition, this method, due to its simple application, becomes low-cost for the end user.

Figure 1 shows a perspective view of the boiler room with all the components of the automatic boiler temperature control system assembled and placed in their positions inside and outside the room.

Figure 2 shows a perspective view of the articulated arm with the servo motor and coupler of the automatic boiler temperature control system, for cases where the temperature controller is located on the front of the boiler.

Figure 3 shows a perspective view of the articulated arm with the servomotor and coupler of the automatic boiler temperature control system, for the cases where the temperature controller is located on the upper side of the boiler.

Figure 4 shows a perspective view of the articulated arm with the servo motor and coupler of the automatic boiler temperature control system, showing the locations of the three neodymium magnets on the feet of the articulated arm base.

Figure 5 shows a perspective view of the central control unit of the automatic boiler temperature control system, showing the display and the rotary switch located on the front.

Figure 6 shows a perspective view of the central control unit of the automatic boiler temperature control system, showing the positions of the three neodymium magnets on the feet of its base.

Figure 7 shows a perspective view of the coupler with the bolt and nut of the automatic boiler temperature control system.

Fig. 8 shows a perspective view of all the parts that make up the cylindrical housing of the outdoor ambient temperature sensor.

Automatic boiler temperature control system (1 ) by the method of turning the rotary temperature regulator (7) of the boiler, through a servo motor (9) whose angle of rotation of its axis depends on the external ambient temperature.

For the drive transmission from the servo motor (9) to the rotary temperature regulator (7) of the boiler, a coupler (8) is inserted, with the possibility of concentric and eccentric movement.

The coupler (8) according to figure 7, consists of three disks (25, 26, 27) with the possibility of sliding in two axes X and Y between them, according to the guides (28) and projections (29) and a screw (24) with a clamping nut (23). During the assembly of the coupler, each protrusion (29) of one disk enters the corresponding guide (28) carried by the next disk, achieving in this way the possibility of sliding in relation to one axis between the upper (27) and the middle (26) disk and the ability to slide with respect to a second axis and perpendicular to the first, between the middle (26) and the lower (25) disk. The role of the screw (24) and the clamping nut (23) is to connect the rest of the coupler body, directly to the shaft of the rotary temperature selector (7) of the boiler (1) as shown in figure 2 and figure 3 respectively with the position of the rotary temperature regulator (7) of the boiler. With this arrangement, the transmission of the rotary movement of the servo motor (9) is achieved even when its axis of rotation is not in a straight line with the axis of the rotary temperature selector (7) of the boiler.

The servo motor (9) is supported by four screws on a base (10) which is the end of an articulated arm (2) which carries five arms (11, 12, 13, 14, 15) which are capable of sliding, rotating and fixed together with screws (17, 18) which connect them, in order to align the axis of the servo motor (9) with the axis of the rotary temperature controller (7) of the boiler (1). To support and immobilize the base (16) of the hinged arm (2) on the metal frame of the boiler (1), strong neodymium magnets (19) have been placed on its three feet as shown in figure 4.

The control of the servomotor (9) is done by the central control unit (3) through the necessary wiring, which are two cables to supply the 5V operating current and one cable to transfer the signal indicating the angle of rotation that must be take the servo motor shaft (9). The control unit consists of the central board that carries the processor with the system operating program, the cover, and as shown in figure 5 and figure 6 a screen (21), a rotary regulator (20) and three neodymium magnets (22 ) for the possible support of the central control unit on the metal cover of the boiler.

The torque angle command that will be sent to the servo motor (9) from the central control unit (3), is the result of the processing of the data collected by the external ambient temperature sensor (6) and the pipe contact sensors (4,5) for the reading of the water temperature of the heating network, from the program running on the microprocessor.

For the accurate measurement of the external ambient temperature, the sensor is placed in a specially made cylindrical housing (6), which, according to figure 8, consists of:

the outer cylinder (33) with diagonal holes which have a direction from the inner upper part to the outer lower part of the cylinder wall and do not allow the rain to penetrate inside,

the inner cylinder (32) with holes which have a horizontal direction, in combination with the holes of the outer cylinder, the reduction of the wind speed to the core of the structure is achieved,

the structure stabilization and tightening component (31) which brings the two cylinders to the correct positions,

the support base of the structure (30) which with four vertical screws holds the individual pieces in their positions and with two horizontal screws allows it to be supported on a vertical surface.

According to figure 1 on the boiler cover (1) are supported the central control unit (3) and the hinged servomotor holding arm (2) with which we can align the servomotor with the rotary boiler temperature controller. The central control unit (3) analyzes the data it receives from the contact sensors on the water pipes of the heating network (4, 5) and the external ambient temperature sensor which is located inside a specially constructed housing (6) to protect it from the weather conditions. The central control unit (3), after analyzing the data according to the program running on the processor and the settings made by the system installer, gives a rotation command to the servo motor (9) which in turn transmits the rotational movement of its axis, through a coupler of concentric and eccentric movement (8) as shown in figure 2, to the rotary temperature regulator (7) of the boiler in order to select the hot water production temperature according to the command of the central control unit.

In this way, the automatic reduction of the boiler hot water production temperature is achieved, inversely depending on the external ambient temperature. As a result, the operating time of the boiler is reduced and consequently a reduction in fuel consumption is observed, which is the final goal.

Claims (6)

CLAIMS AUTOMATIC BOILER TEMPERATURE CONTROL SYSTEM 1. Boiler automatic temperature control system which includes an outdoor temperature sensor placed in the center of a cylindrical housing (6), a temperature sensor (4) of the water entering the boiler (1), a temperature sensor (5) of the water extraction from the boiler (1), the central control unit (3), which collects the data from the water sensors (4,5) and from the ambient temperature sensor placed in the center of a cylindrical casing (6) and then processing of these data according to the program running in the microprocessor of the central control unit (3), the automatic boiler temperature control system turns the rotary temperature regulator (7) of the boiler (1), characterized by the fact that the rotation of the rotary regulator temperature (7) of the boiler (1) is achieved by the servomotor (9) which rests on an articulated arm (2), where the transfer the movement from the servo motor (9) to the rotary temperature regulator (7) of the boiler (1) is done through a coupler (8) that has the possibility of concentric and eccentric movement and the rotation is done in such a way that with the rise of the external temperature environment to reduce the production temperature of the hot water of the boiler (1) and vice versa, with the fall of the external ambient temperature the production temperature of the hot water of the boiler (1 ) increases, 2. Automatic boiler temperature control system according to claim 1, characterized in that the coupler (8) consists of three disks (25,26,27) with the possibility of sliding in two axes X and Y between them, according to the guides ( 28) and the projections (29) and a screw (24) with a clamping nut (23). During the assembly of the coupler (8), each protrusion of one disk enters into the corresponding guide carried by the next disk as shown in figure 7, achieving in this way the possibility of sliding in relation to one axis between the upper (27) and of the middle (26) disk and the ability to slide about a second axis and perpendicular to the first, between the middle (26) and the lower (25) disk. The role of the screw (24) and the clamping nut (23) is to connect the rest of the coupler body (8) directly to the shaft of the rotary temperature regulator (7) of the boiler (1). With this arrangement, the transmission of the rotary movement of the servomotor (9) is achieved even when its axis of rotation is not in a straight line with the axis of the rotary temperature regulator (7) of the boiler. 3. Boiler automatic temperature control system according to claim 1, characterized in that the body of the servo motor (9) is based with the help of four screws on a base (10) of corresponding dimensions and shape which is the end of an articulated arm (2) . The arm consists of the base (10) of the servomotor (9), 5 movable parts (11,12,13,14,15) and a base for supporting them (16), so that it is possible to place the servomotor (9) in any position of the three axes of space X, Y, Z resulting in the correct approach and alignment to the axis of the rotary temperature selector (7) of the boiler (1). For the case that the rotary temperature controller (7) of the boiler (1) is located on top of it (Figure 3), less than 5 arms can be used in order to align the servomotor (9) with it. 4. Automatic boiler temperature control system according to claim 1, characterized in that the rotational position that the servomotor shaft (9) will take in any case is the result of an algorithm running in the processor of the central control unit (3) directly dependent from the data collected by the external ambient temperature sensor located in a specially constructed cover (6) and the water temperature sensors (4, 5) of the heating network. 5. Boiler automatic temperature control system according to claims 3 and 4, characterized in that the support of the bases of the system with the metal shell of the boiler (1) is achieved by fitting three neodymium magnets, one on each foot (19) of base (16) of the articulated arm (2) and three neodymium magnets on the base (22) of the central control unit (3). 6. Automatic boiler temperature control system according to claim 1, characterized in that the cylindrical casing of the outdoor temperature sensor (6) consists of four parts according to figure 8. The outer cylinder (33) with diagonal holes which they run from the inner top to the outer bottom of the cylinder wall and prevent rain from entering the interior. The internal cylinder (32) with holes which have a horizontal direction, in combination with the holes of the external cylinder, achieves the reduction of the wind speed up to the core of the structure. The structure stabilization base (31) which brings the two cylinders to the correct positions. The structure support base (30) which with four vertical screws holds the individual pieces in their positions and with two horizontal screws allows the entire structure to be supported on a vertical surface.