RU2293922C2 - Heating arrangement - Google Patents

Abstract

FIELD: the invention refers to a heating arrangement with a radiator equipped with branch pipes of feeding and taking off lines and also with a block of temperature sensors installed with possibility of heat exchanging with the indicated branch pipes of the feeding and the taking off lines.

SUBSTANCE: the heating arrangement is fulfilled with a radiator equipped with branch pipes of the feeding and the taking off lines, and also with the block of temperature sensors installed with possibility of heat exchanging with the indicated branch pipes of the feeding and the taking off lines. At that the branch pipe of the feeding line and the branch pipe of the taking off line pass through an adapter and the block of temperature sensors is installed with possibility of heat exchanging with the adapter. At that a data processing arrangement is fixed to the adapter with using a joint connection.

EFFECT: simplification of mounting.

9 cl, 4 dwg

Description

The invention relates to a heating device with a radiator equipped with nozzles for the supply and outlet lines, as well as a block of temperature sensors installed with the possibility of heat exchange with the indicated nozzles of the feed and outlet lines.

For more economical energy consumption, it is necessary to take into account the heat consumption in the radiator as accurately as possible. Heat consumption is taken into account, in particular, in order to distribute the costs arising from heating between individual consumers.

A heating device of this type is known, for example, from patent document DE 3243198. It comprises a flow temperature sensor, a temperature sensor for the discharge line and a room temperature sensor. Additionally, a sensor is provided with which you can determine the "Open" position of the valve that regulates the flow of coolant through the radiator. Based on the measured values and data coming from these sensors, the heat consumption in the radiator is taken into account quite accurately. However, this technical solution is associated with a relatively expensive electrical installation, since the sensors in the supply and outlet lines must be wired with an analog-to-digital converter and a microcomputer.

A similar design is also known from patent document DE 4131563. It also contains a computing device connected to a room temperature sensor and sensors that record the temperature in the supply and outlet lines.

DE 19749623 describes yet another heating device of the above type, comprising a radiator control device. This device has means for measuring the temperature of the air around the radiator and means for controlling the amount of liquid supplied to the radiator. In addition, this device uses means to measure the temperature of the liquid entering and leaving the radiator. The device can be controlled remotely, for example, by means of wires connecting it to a central or decentralized system.

Naturally, the registration of temperature in the supply and discharge lines of the specified device allows you to determine the heat consumption. However, this technical solution has drawbacks, which are ugly in appearance and significant installation costs, because in order to connect the sensors to the control unit or data processing unit, it is necessary to use wires.

Thus, the object of the present invention is to simplify installation.

This problem in the case of a heating device of the aforementioned type is solved due to the fact that the pipes of the supply and outlet lines pass through the adapter, and the temperature sensor unit is installed with the possibility of heat exchange with the adapter.

This design provides the ability to place temperature sensors on the adapter, so the sensors are located next to each other and take up little space. This allows you to abandon the interfering and conspicuous parts that can adversely affect the appearance of the radiator. Installation costs are negligible. When installing a radiator, it is only necessary to ensure the possibility of heat exchange between the temperature sensor block and the adapter. This is a relatively simple measure in which there is no need to introduce branch pipes of the supply and outlet lines to another place.

Preferably, the adapter is in the form of an H-shaped module. The H-shaped module is a common adapter for connecting the supply and outlet lines. The use of such an adapter is known from the prior art for connecting a radiator to pipelines laid in a building. Such an H-shaped module may further comprise a valve for regulating a fluid or other coolant flowing through a radiator.

In a preferred case, a data processing device is attached to the adapter. With this design, temperature data are processed directly "in place", i.e. There is no need to use any external wires between the temperature sensor unit and the data processing device. In this case, the data processing device contains all the components necessary for determining the heat consumption. These components may include a microprocessor or some other computing device. However, you can use an electronic circuit that determines the heat consumption in an analog or digital way based on data from temperature sensors.

In a preferred case, the data processing device is mounted on an adapter using a detachable connection. This design has several advantages. Firstly, the data processing device can be removed from the adapter to, for example, change the battery or read data on the heat consumption. Secondly, installation is simplified. The data processing device can be manufactured separately from the adapter, and then attach it to the adapter.

In a preferred case, the data processing device is attached to the adapter using a snap connection. The latch connection, also referred to as the connection with the locking protrusion, may contain, for example, two grippers made with the possibility of elastic interaction when moving towards each other. These grips, for example, can span the protrusion formed on the adapter with a clamp. The snap connection may also partially cover the connecting pipes and, after overcoming a certain pressure, engage with these pipes.

Preferably, the data processing device comprises a room temperature sensor. The use of such a sensor allows the use of room temperature data to measure heat consumption. One possibility of this kind is shown, for example, in patent document DE 19749623. In this case, data on the position of the valve regulating the amount of coolant flowing through the radiator are no longer necessary.

Preferably, the indoor air temperature sensor is fixed on the side of the data processing device that is opposite to the adapter. In this case, the data processing device serves as a thermal barrier, i.e. the heatsink temperature only slightly affects the sensor readings. However, despite the fact that thermal insulation is preferred, it is usually not used, because if the indoor air temperature sensor is located at a certain distance from the adapter due to the data processing device, then the air temperature can be determined quite accurately and without insulation. The room air temperature sensor can be placed in another place, provided that it will be there in the same or even more favorable conditions.

In the preferred case, the temperature sensor unit is rigidly connected to the data processing device and, thanks to the fastening of this device to the adapter, is pressed against the outside of the adapter. When manufacturing a data processing device, it is possible to simultaneously install a block of temperature sensors. The advantage of this solution is that the sensor unit can be checked together with the data processing device. The possibility of heat exchange between the temperature sensor unit and the adapter is ensured by the fact that the sensor unit is pressed against the outside of the adapter due to the force with which the data processing device is held on the adapter. As a result of this, there is sufficient heat exchange between the adapter and the temperature sensor assembly to measure heat consumption.

In one of the alternative designs, it can also be provided that the temperature sensor assembly is embedded in the adapter. In this case, when attaching the data processing device to the adapter, it should only be possible to transmit signals from the sensor unit to the data processing device. This possibility is realized, for example, due to the fact that when the data processing device is attached to the adapter, a detachable connection is provided.

Preferably, the temperature sensor assembly should have separate sensors for the supply pipe and the branch pipe. In this case, it is possible to obtain a first temperature signal in the supply pipe and a second temperature signal in the discharge pipe. This allows a relatively simple measurement of heat consumption to be realized.

In one of the alternative designs, it can be provided that in the sensor block there will be one common sensor for the supply pipe and the branch pipe, which is located in the middle between these pipes from the point of view of heat transfer. In other words, the common sensor determines the average value between the temperature in the flow line and the temperature in the bypass line. With a symmetrical design of the data processing unit, this can be realized, for example, due to the fact that the sensor is located in the middle between the supply pipe and the branch pipe. If, due to design features, asymmetry occurs, for example, a large thickness of the material in the zone of the supply pipe, then this asymmetry must be taken into account when placing the sensor.

Next, with reference to the accompanying drawings, preferred embodiments of the invention are described.

Figure 1 depicts a simplified diagram of a heating device.

Figure 2 depicts a first embodiment of an adapter.

Figure 3 depicts a second variant of the adapter.

4 shows a third embodiment of an adapter.

Figure 1 shows a heating device 1 with a radiator 2, equipped with a pipe 3 of the supply line and pipe 4 of the outlet line.

The heat supply communication wiring from the wall or floor 5 exits with the supply pipe 6 and the discharge pipe 7. The connection between the supply pipe 6 and the pipe 3 on one side and the drain pipe 7 and the pipe 4 on the other hand is provided by an adapter 8 made in the form of an H-shaped module. If the nozzles 3 and 4 form straight lines with the inlet pipe 6 and the outlet pipe 7, as shown in FIG. 1, then the adapter 8 does have the shape of the letter N. However, in many cases, the inlet pipe 6 and the outlet pipe 7 do not exit from the floor 5 but from the wall. In this case, the adapter 8 contains fittings for the inlet pipe 6 and the outlet pipe 7, which are directed towards the wall, as shown in Fig.2-4.

In the case of the structure shown in FIG. 1, a temperature-regulating nozzle 9 is installed on the adapter 8, with which it is possible to set a predetermined temperature in the room. In addition, on the adapter 8 is placed the sensor 10 of the flow temperature and the sensor 11 of the temperature of the outlet line. The sensor 10 determines the temperature in the pipe 3 of the flow line. The sensor 11 determines the temperature in the branch pipe 4 of the discharge line 4. Even if the temperature sensors 10 and 11 do not directly determine the temperature of the coolant flowing through the pipe 3 of the supply line and the branch pipe 4 of the discharge line, then to obtain data on the basis of which fuel consumption can be taken into account, it is enough to determine the temperature of the pipes forming both pipes 3 and 4. In this case, it is advisable to carry out the corresponding pipes or elements of the adapter 8 from a material having good thermal conductivity.

In addition, a data processing device 12 is installed on the adapter 8, in which a room temperature sensor 13 is placed. The data processing device 12 is connected to a flow temperature sensor 10 and a flow line temperature sensor 11. Based on the temperature in the supply and discharge lines, as well as the room temperature, it is possible to determine the heat consumption, for example, by the method described in patent document DE 19749623.

The first embodiment of the adapter 8 is shown in figure 2. Similar elements are indicated here by the same reference numbers as in FIG.

The adapter 8 is shown in FIG. 2a in cross section, in FIG. 2b in front, and in FIG. 2c from above. It has a housing 14, equipped with a first connecting element 15 for mounting the nozzle 3 of the supply line and a second connecting element 16 for mounting the nozzle 4 of the discharge line. Naturally, it can be done so that the supply pipe will interact with the second connecting element, and the branch pipe with the first connecting element (not shown here). Both connecting elements can be equipped, for example, with a union nut 17 and seals 18. The sensor 10 for the temperature of the supply line is located in the area of the supply channel 19, and the temperature sensor 11 in the outlet line is located in the area of the outlet channel 20. Sensors 10 and 11 can be integrated into case 14, for example, they can be sealed into the hole provided in the case 14.

The feed channel 19 passes into the valve 21, designed to control the coolant flowing through the radiator 2. At the end of the valve 21, which protrudes from the housing 14, there is a connecting element 22, used to secure the thermostatic nozzle 9.

The data processing device 12, which in this case is made in the form of an electronic unit, is mounted on the housing 14 by means of a clamp, that is, it is attached to the housing 14 by means of a snap connection (not shown). The room temperature sensor 13 is installed on the side of the data processing device 12, which is the farthest from the housing 14. Due to this, the temperature of the housing 14 has a minimal effect on the operation of the sensor 13.

Figure 3 shows another embodiment of the invention, and for the structures shown in figures 3 and 2, the same and corresponding elements are denoted by the same reference numbers.

In this embodiment, the flow temperature sensor 10 and the outlet temperature sensor 11 are provided in the housing of the data processing device 12. Due to the fact that the data processing device 12 is connected to the housing 14 of the adapter 8, the sensors are in contact with the possibility of heat exchange with the housing element 23, which covers the branch pipe, and with the housing element 24, which covers the branch pipe. This circumstance allows you to determine the temperature of these pipes.

In the design shown in FIG. 4, only one temperature sensor 25 is used. This sensor 25 determines the average value of the temperatures in the supply and outlet lines.

In the structure shown in FIG. 2, when the data processing device 12 is attached to the adapter 12 using a detachable or other connection, a contact is created between the data processing device 12 and the sensors 10 and 11. In the case of the structure shown in FIGS. 3 and 4, such the contact is not even needed, since temperature sensors (10 and 11 or 25, respectively) are integrated into the data processing device 12.

The latch connection with which the data processing device 12 is attached to the adapter 8 can be realized, for example, by the presence of U-shaped clamping blocks (pads not shown in detail) on the data processing device 12, which cover the elements 23, 24 and (or ) 26, 27 of the building, i.e. elements located in the axial extension of the valve 21.

In many cases, it is advisable to install the data processing device 12 in such a way that it can be used to recognize possible manipulations and attempts to dismantle the unit. In such cases, the result processing device 12 is either impossible to dismantle at all, or a special tool is needed for this, or the device is destroyed when dismantled. This allows you to use the data processing device in the calculations for the use of heat, when any attempts to cheat immediately become noticeable.

If necessary, the data processing device may have additional mechanical protection. This provides adequate radiator protection against vandalism.

The data processing device 12 may also include equipment for remotely reading a set fuel consumption. In this case, the controller no longer needs to go to the radiator in order to read the flow rate. Moreover, fuel consumption can be displayed in a remote location. The set values are transmitted to the indicator device via wired or wireless lines.

The presented invention allows deviations from the considered design options. Instead of a thermostatic actuator with a bellows, another type of actuator, such as a wax, can be used. In addition, the sensor 13 of the room temperature can be installed in another place, for example at any point on the outside of the data processing unit.

Claims (9)

1. A heating device with a radiator equipped with branch pipes for the supply and outlet lines, as well as a temperature sensor unit installed with the possibility of heat exchange with the indicated branch pipes for the supply and outlet lines, characterized in that the branch pipe (3) of the supply line and the branch pipe (4) of the branch line pass through the adapter (8), and the temperature sensor block (10, 11; 25) is installed with the possibility of heat exchange with the adapter (8), and a data processing device (12) is attached to the adapter (8) using a detachable connection. 2. The device according to claim 1, characterized in that the adapter is made in the form of an H-shaped module. 3. The device according to claim 2, characterized in that the data processing device (12) is attached to the adapter (8) using a snap connection. 4. The device according to claim 3, characterized in that the data processing device (12) comprises a room temperature sensor (13). 5. The device according to claim 4, characterized in that the room temperature sensor (13) is installed on the side of the data processing device (12) that is opposite to the adapter (8). 6. The device according to claim 5, characterized in that the temperature sensor unit (10, 11; 25) is rigidly connected to the data processing device and, thanks to the fastening of the data processing device (12) to the adapter (8), is pressed against the outside of the adapter (8) . 7. The device according to claim 6, characterized in that the temperature sensor unit (10, 11) is embedded in the adapter (8). 8. The device according to claim 7, characterized in that the temperature sensor unit contains separate sensors (10, 11) for the branch pipe (3) of the supply line and branch pipe (4) of the outlet line. 9. The device according to claim 8, characterized in that the temperature sensor unit has a common sensor (25) for the branch pipe (3) and the branch pipe (4), which, from the point of view of heat transfer, is located in the middle between the pipe branch (3) and branch pipe (4) of the discharge line.

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