WO2020035273A1 - Measuring device for measuring the volumetric flow rate of water in a heating circuit - Google Patents

Abstract

The invention relates to a measuring device for measuring the volumetric flow rate of water in a heating circuit of a heating system of a volumetric flow rate sensor. To that end, there is provided, in a bypass to the volumetric flow rate sensor, a bypass valve with a bistable diaphragm, which closes at low volumetric flow rates and guides all of the flow through the volumetric flow rate sensor and which, in the case of high volumetric flow rates, guides only a defined partial flow through the volumetric flow rate sensor. The measuring device is particularly well-suited to measuring small volumetric flow rates and to giving rise to no large pressure loss.

Description

 Measuring device for measuring the volume flow of water in a heating circuit

The invention relates to a measuring device for measuring the volume flow of water in a heating circuit of a heating system, a volume flow sensor.

In heating systems, heat that is generated for the heat distribution is by means of circulating heating water with a pump through a heat exchanger

Radiators, underfloor heating and the like promoted. Because each heating system is unique, it has a different number of radiators and other additional devices, using control systems. The setting and control of the equipment in the rooms of the circulating heating water can be adapted to the current needs. In modern systems, this adaptation to the heat requirement leads to low volume flows in the heating system.

In addition to other data, information about the volume flow in the heating circuit is necessary to ensure regulation. Volume flow sensors are used to obtain this information.

Volume flow sensors are preferred, which are based on measuring principles, which do not require any moving parts, which do not cause large losses in their fluid circuits

Cause internal resistances and which do not require a complex evaluation system. Examples of such measurements are sensors based on the vortex principle. The vortex sensor has a lower limit and an upper limit of the measuring range, and there are some restrictions in use. The sensor, which is suitable for measuring smaller flows, causes a relatively high pressure loss. One sensor with another Measuring range has a sufficient pressure loss, but not sufficient accuracy with a low volume flow. Alternatively, there are also sensors with a wide one

Measuring range available, which can also record small flow rates. However, these sensors are very expensive.

Since the measurement of small volume flows in modern heating systems is an important requirement, methods for measuring low volume flows by expanding the measuring range of the volume sensors are described, such as the method disclosed in EP 2757324 A2. This describes a measurement arrangement that is suitable for measuring smaller volume flows for a small output (for example as long as radiators were open), but also to deliver high output at high volume without a large pressure loss. A pressure-dependent valve with hysteresis behavior and reduced pressure loss is used for this. Such a function can be realized by a device that consists of a differential pressure sensor, an electromagnetic valve and a drive that requires control. As a result, the method disclosed in EP 2757324 A2 is disadvantageous owing to the complexity and the associated costs.

It is therefore an object of the invention to provide an inexpensive measuring device for measuring the volume flow of water in a heating circuit of a heating system with an extended measuring range.

According to the invention this object is achieved by a measuring device according to claim 1. Advantageous refinements result from the features of the dependent claims. The bypass valve has an orifice, which is a bistable and therefore binary

Valve openings “open” and “closed” are possible without intermediate positions and, in contrast to known spring valves, cause very little pressure loss when open. The shut-off mechanism is implemented by a bistable aperture, which, like a cracked frog, either remains in a position that fully opens the bypass valve or in a position that is closed to the bypass valve. The orifice only jumps to the other bistable position when certain pressure differences are exceeded or fallen below. A hysteresis function is thus achieved. This is indicated by an at least partial curvature, e.g. in the form of a bend or a bead around an axis perpendicular to the crease line.

The bypass valve is connected in parallel to the volume flow sensor and realizes a bypass for the flow meter. This measuring device thus fulfills the requirement to measure small volume flows and thus the conditions for a small pressure loss.

In one method, the position of the orifice is determined either by means of a sensor or by registering the volume flow signal of the flow sensor. If the aperture jumps into the other bistable position, the measured value increases or decreases

Volume flow of the volume flow sensor suddenly. This is saved so that it is known at all times what position the aperture is in. When determining the total volume flow, the volume flow of the volume flow sensor is then used with the bypass valve closed. When the bypass valve is open, the volume flow of the volume flow sensor is determined by the volume flow portion of the volume flow sensor

Total volume flow divided. This proportion is known and unchangeable and can be calculated on the basis of the structural design or measured once.

In particular, it can easily be measured during operation at the time of switching the diaphragm. Alternatively, the volume flow can also be determined with the help of the operating parameters of the pump when the bypass valve is open. This is known from the state of the art.

The invention will now be explained in detail with reference to the figures.

[0013] The figures show:

 Figure 1: Bypass valve with the orifice closed

Figure 2: Bypass valve with the orifice open

 Figure 3: A heating circuit with the measuring device according to the invention

Figure 1 shows the bypass valve 4 with the diaphragm closed. The bypass valve 4 with the diaphragm open is shown in FIG. 2. The bistable opening behavior of the orifice 7 of the valve 4 can be achieved by a thin spring steel sheet 7, which is introduced into the flow in a sealing manner with a bend at right angles to the sheet metal clamping 6. The introduced bend has the constructive effect of a bead, which means that

Spring steel sheet 7 is stiffened and therefore a considerably greater force must be applied for deformation in the direction of flow. With increasing differential pressure upstream and downstream of the orifice 7, the force to be applied in order to deform the bead and bend the spring steel sheet in the flow direction increases until that applied by the bead

Resistance of the spring steel sheet 7 has been overcome and the diaphragm abruptly opens completely, since the force required for the further bending of the spring steel sheet 7 without a bead is substantially less than the force already applied. A quasi digital opening behavior is brought about by the described deformation characteristic. In the open state, flows with very low pressure losses can be realized in this way. The closing behavior is similar to that of a conventional, spring-loaded valve until the deformation threshold to the initial state is reached and the valve closes abruptly. Figure 3 shows a schematic representation of a heater 1 with a heating circuit 10 with a primary heat exchanger 2, with a circulation pump 3 and with the

Measuring device 9 according to the invention. The measuring device 9 comprises a

Volume flow sensor 5 and, in parallel, a bypass 8 with a bypass valve 4.

The advantage of the measurement arrangement shown in FIG. 3 is that in the case of small and medium volume flows only the volume flow sensor 5 is flowed through, since this is where the volume flow sensor 5 is optimally used. In operating points with high volume flows, the flow is led through the bypass 8, since the pressure losses are lower here.

LIST OF REFERENCE NUMBERS

 1 heater

 2 primary heat exchangers

3 pump

 4 bypass valve

 5 volume flow sensor

6 aperture clamping

7 aperture

 8 bypass

 9 measuring device

10 heating circuit

 11 axis

 12 crease line

Claims

1. Measuring device (9) for measuring the volume flow of a heat transfer medium circulated by means of a pump (3) to a heating circuit (10), the measuring device comprising a volume flow sensor (5) and a bypass (8) with a bypass valve (4), the volume flow sensor (5) has a lower and an upper limit of its measuring range and the measuring range of the measuring device (9) is larger than that of the volume flow sensor (5), the volume flow sensor (5) and the bypass valve (4) controlled by the bypass valve (4) in parallel are switched so that the bypass valve (4) can deflect a defined part of the volume flow to be measured by the measuring device (9) parallel to the volume flow sensor (5), characterized in that the bypass valve (4) comprises an integrated flexible orifice (7), wherein the diaphragm (7) a first bistable state in which the flow through the bypass valve (4) opens and a second bistable state in which the flow du rbypass valve (4) is blocked, can take and if the differential pressure between the inlet and outlet of the bypass valve (4) is high, the orifice (7) is opened to the bistable state and if the differential pressure between the inlet and outlet of the bypass valve (4 ) the orifice (7) is transferred to the bistable state in a blocked state, the measuring device (9) being designed so that the high differential pressure is present when the orifice (7) in the closed state exceeds the upper limit of the measuring range of the volume flow sensor (5) and that the low differential pressure is present when, when the orifice (7) is open, the value falls below the lower limit of the measuring range of the volume flow sensor (5).

2. Measuring device according to claim 1, characterized in that the flexible diaphragm

(7) consists of thin spring plate.

3. Measuring device according to claim 2, characterized in that the flexible diaphragm (7) is at least partially curved about an axis (1 1), that the diaphragm can be bent about a kink line (12) and that the axis (11) in the plane of Aperture (7) are approximately perpendicular to each other.

4. Measuring device according to one of claims 1 to 3, characterized in that the measuring device comprises a sensor which determines the position of the flexible diaphragm.

5. Measuring device according to one of claims 1 to 3, characterized in that the measuring device comprises a control device which is designed such that the direction of the last measured sudden changes in the volume flow signal is stored.

6. A method of operating a measuring device according to one of claims 1 to 5, comprising the method steps

 Measuring the volume flow flowing through the volume flow sensor,

 Determining the position of the flexible orifice of the bypass valve by means of a sensor or by reading out the stored direction of the last measured abrupt changes in the volume flow signal,

 - if the bypass valve is closed: output the measured

 volume flow

 - if the bypass valve is open: output the measured volume flow of the volume flow sensor divided by the defined portion of the

Volume flow sensor flow at the flow of the entire measuring device.

7. The method according to claim 6, characterized in that, when the bypass valve is open, deviating from the volume flow is determined based on the operating parameters of the pump (3).