DE10243170A1 - Heat pump for building heating installation has integral condenser and volume of boiler in contact with heat exchanger kept within set heating range - Google Patents

Abstract

The heat pump for a heating installation has an integral condenser (3) receiving through flow of a coolant and in heat exchange contact with the heating fluid. The volume of the water boiler (2) which stays in heat exchange contact with the condenser is determined so that, in a non-turbulent heating fluid flow there is not more than 5 degrees Kelvin heating per minute of operation of the pump.

Description

The invention relates to a heating system a heat pump and one into the heat pump integrated, with refrigerant flow through refrigerant condenser, the one in heat conductive There is contact with the heating water.

In the DE 100 24 044 A1 A heat pump is shown which is driven by wind energy and in which the evaporator and condenser, depending on whether the system works as a heat or cold generator, is integrated directly in the buffer storage for heating.

A heat exchanger of a heat pump with a pot-like refrigerant condenser is out of the DE 31 50 470 A1 known. In this heat exchanger, the hot gas from the refrigerant circuit flows into a container which is interspersed with a number of pipes for hot water. These tubes serve as refrigerant condensers for the hot gas introduced into the tank.

From the US 4,371,036 a heat exchanger for use in a heat pump is known. One or several pipes for the conduction of refrigerant are arranged in a spiral around a central line. This tube arrangement for the flow of refrigerant is arranged within a container with a jacket through which water flows. The water, which is described here as a heat-carrying medium, flows through the jacket tube or the container in the same direction as the refrigerant flows through the spirally wound tubes.

According to a method and a heating system for heating buildings DE 199 38 019 A1 a condenser is arranged outside a heat pump in a hot water tank. The condenser is integrated into the cooling circuit of the heat pump via a refrigerant circuit line.

With the known methods therefore heat pumps known where the heat transfer of the refrigerant on the heating medium with a heat exchanger takes place, which works in countercurrent or cocurrent and thus a direct heat transfer the heat output offered by the heat pump to the heating medium allows. at In other systems, the condenser of the heat pump is in one of the heat pumps independently attached hot water tank, with which one of the delivery of the heating energy of the heat pump largely independent Storage mass for thermal energy is provided.

Water storage integrated in the heat pump are known. Particularly advantageous for the once-through heat generators is that the mean temperature difference between the heated water and the heated condensing in the once-through heat generator and hypothermic refrigerant can be kept small.

The object of the invention is a heat pump to be designed so that even if the Volume flow of the heating medium ensures that the heat pump functions reliably guaranteed remains, a controlled shutdown of the heat pump takes place and at the same time the mean temperature differences between the refrigerant and the heating water if possible are small.

The task is solved by the Measures of the Characteristic of claim 1.

The refrigerant condenser one heat pump is in the

heat pump self-integrated and part of the heating system. The refrigerant condenser, in the refrigerant condensed, is inserted in a heating water boiler, which also Part of the heat pump is. This is characterized by the fact that it has such a large volume of water implies that for the heat exchange of condensing refrigerant available on the water area is so big that from the heat pump generated heating energy from the refrigerant possible on the resting heating medium is. The heating medium is at rest if, for example, the circulation pump the heating system fails. In this case it’s still appropriate that Volume of the heating medium to be designed so that the temperature of the heating medium increases by about 5 K per minute. With a heat output of the heat pump of 10 kW would result approximately a water volume of 30 l.

To a control shutdown or a to be able to regulate thermally controlled operation of the heat pump at least one temperature sensor arranged in the heating water boiler. Are advantageous two temperature controllers, one in the area of the heating water flow and one in the area of the heating water return. About the Temperature spread between flow and return temperature in the heating water boiler even the interruption of the volume flow of the heating medium can be detected and the heat pump via a Control shutdown limited during operation. There is no pressure increase in the Refrigeration circuit, whereby in the event of failure to detect the failure of the heating medium volume flow the high pressure monitor (HD monitor) heat pump performs an emergency shutdown. By the so-called HD guard initiated emergency shutdown requires the use of a customer service mechanic, the on-site heat pump back in proper condition move back got to.

By detecting the temperature spread between the temperature sensor of the flow and return temperature and a volume of the heating water boiler, which is 30 l, for example, at 10 kW heating power of the heat pump, he This is followed by the reliable detection of the failure of the heating medium to flow through the heating water boiler, and the heating energy supplied by the heating pump until the heat pump is switched off is absorbed by the mass of the heating medium in the heating water boiler to such an extent that an emergency shutdown via the high-pressure monitor does not take place.

By arranging the connection the heating flow in the upper area of the heating water boiler and the heating return in the lower part of the heating water boiler is in the heating water boiler an energetically favorable Temperature stratification achieved. A thermal stratification of the heating medium temperature in the heating water boiler is due to the embodiment of the refrigerant condenser reached in three different areas. From top to bottom in the heating water boiler the refrigerant heater is arranged, followed by one in the central area of the heating water boiler Refrigerant condenser and in the lower area of the heating water boiler followed by a refrigerant subcooler. The The effect of temperature stratification is still achieved that the store runs lean is and the relationship the height to the diameter like approx.> 1.5: 1 behaves.

With the temperature stratification is it still possible on a circulation pump for the To waive heating medium. about The natural Convection of the water takes place in the heating water boiler, a buoyancy movement, which is sufficient to circulate the heating medium in the heating circuit. By This measure the failure of a non-existing circulation pump is excluded, i.e. the Possibility, that the heating medium volume flow comes to a standstill, is reduced by the error potential of the failure of the circulation pump.

Furthermore, the integrated Heating water boiler the overflow valve otherwise required for serial buffer tanks saved.

The minimum water volume of the heating water boiler can be calculated as V _min [I] = Q [kW] × 2.87, whereby another condition is the permissible temperature rise of 5 K / min.

In a further advantageous embodiment of the heating water boiler, its maximum size is calculated using the formula V _max [I] = Q [kW] × 8.61. It is taken into account that the construction volume of the heat pump is as small as possible and the condition of the permissible temperature increase of 5 k / min is met.

The refrigerant condenser can advantageously in the heating water boiler itself, e.g. as coiled tubing in the heating water boiler or as a rollbond heat exchanger around the heating water boiler be arranged around. Another component of integration is it is advantageous to have direct electric heating in the heating water boiler to be installed at a specified flow and / or return temperature is switched on automatically.

Show in the drawing

1 a heat pump schematically with a heating water boiler and a refrigerant condenser of the refrigerant circuit integrated in the heating water boiler,

2 a diagram with a range for the volume of a heating water boiler as a function of the heating output,

The heat pump 1 has one in a heating water boiler 2 integrated refrigerant condenser 3 on. This is for temperature stratification in the heating water boiler 2 in three areas, namely the refrigerant heater 4 , the refrigerant condenser 5 and the refrigerant subcooler 6 divided in the lower area. Direct electrical heating 7 in the form of a tubular heater, for example, which is coiled or meandering, is also in the heating water boiler 2 arranged. The refrigerant circuit of the heat pump 1 still consists of an expansion valve 8th , an evaporator 9 as well as a compressor 10 , The heating water boiler has a connection in the lower area 11 for a return line, not shown, and a connection 12 up in the heating water boiler for a flow line of a heating system, not shown. The temperature sensors are connected to a control, not shown 13 . 14 connected. The temperature sensor 13 is used to measure the storage tank temperature t _V in the upper area of the heating water boiler ( 2 ), which essentially determines the flow temperature. The temperature sensor located at the bottom of the heating water boiler 14 is used to measure the return temperature t _R in the storage tank.

In 2 is a range by a lower short V _min [I] and an upper short V _{m ax} [I] 4 ) the volume of the heating water boiler 2 limited, in which the boundary condition of the permissible temperature increase of 5 k is met. In addition, in area B, which is open at the top, the condition of permissible temperature increase of 5 k also applies, but a reasonable size of the boiler has been exceeded.

Claims (11)

Heat pump for a heating system with an integrated refrigerant condenser through which refrigerant is in heat-conducting contact with the heating medium, characterized in that the volume of a heating water boiler ( 2 ) with which the refrigerant condenser ( 3 ) is in heat-conducting contact and / or in which the refrigerant condenser ( 3 ) is so dimensioned that the dormant heating medium in it is in the absence of forced circulation increase by no more than 5 K during one minute of operation of the heat pump ( 1 ) heated, and the volume of the heating water boiler ( 2 ) depending on the heat output of the heat pump ( 1 ) according to V [I] = Q [kW] × Z, where Z = <2.87 applies. Heating system according to claim 1, characterized in that the height of the heating water boiler ( 2 ) is at least 1.5 times its diameter or cross-section. Heating system according to claim 1 or 2, characterized in that the refrigerant condenser ( 3 ) in a heating water boiler filled with heating water ( 2 ) and / or the refrigerant condenser ( 3 ) around the heating water boiler ( 2 ) is arranged around. Heating system according to one of the preceding claims, characterized in that the refrigerant condenser ( 3 ) as coiled tubing in the heating water boiler ( 2 ) is arranged almost over its entire inner height. Heating system according to claim 1, 2 or 3, characterized in that the refrigerant condenser ( 3 ) as a roll bond heat exchanger around the heating water boiler ( 2 ) is laid around from the outside. Heating system according to one of the preceding claims, characterized in that the refrigerant condenser ( 3 ) in three functional areas desuperheater ( 4 ), Condenser ( 5 ) and subcooler ( 6 ) is divided. Heating system according to one of the preceding claims, characterized in that the heating flow (t _V ) in the upper area and the heating return (t _R ) in the lower area of the heating water boiler ( 2 ) is arranged. Heating system according to claim 1, characterized in that the heating water boiler ( 2 ) is determined in its maximum volume by the dependence V [I] = Q [kW] × 8.61. Heating system according to claim 1 or 2, characterized in that in the heating water boiler ( 2 ) direct electrical heating ( 7 ) is installed. Heating system according to claim 9, characterized in that when a predetermined flow (t _V ) and / or return temperature (t _R ) is undershot by a control ( 4 ) automatic direct heating ( 7 ) is switched on. Heating system according to one of the preceding claims, characterized in that in the heating water boiler ( 2 ) at least one temperature sensor is arranged, which sends a temperature value to the control ( 4 ) transmitted, or that with several temperature sensors ( 13 . 14 ) the temperatures to the control ( 4 ) are transmitted, a mixed value of the heating water temperatures is formed and either the temperature value, the mixed value or the differential value of the heating water temperatures in the control ( 4 ) is processed.