In the National Climate Agreement, the Dutch government has set the goal of reducing Netherlands’ greenhouse gas emissions by 49% in 2030 compared to 1990 levels. By 2050, this number should even have risen to 95%. Part of the greenhouse gas emissions is the generation of electricity by means of coal and natural gas. In order to contribute to the reduction of greenhouse gas emissions, the Dutch government has set a target that 70% of electricity must be generated from renewable sources by 2030. Last year, 18% of electricity was generated from renewable sources. 24% of this was generated by solar power. Solar power can be generated through solar panels on roofs, on the ground, and on the facade. Solar panels on the roof are often sufficient for a single-family dwelling to generate enough energy for their own use. However, there are many buildings where the roof surface is limited in relation to the user surface. The facade surface is often larger than the roof surface. In order to make optimal use of the energy potential of facades, new facade claddings are needed that make it possible to generate energy through the facade. One of the possibilities is the integration of PhotoVoltaics in a High Pressure Laminate (HPL) facade panel. However, this has an impact on the installation of the product and has other requirements. In this master thesis, research has been done into the requirements, design and development of an easy-to-use facade system for mounting High Pressure Laminate facade panels with integrated PhotoVoltaics on the facade. The research is divided into several phases. In the first phase, the requirements for the High Pressure Laminate Building-Integrated facade system are researched trough literature research. This included the properties of the material High Pressure Laminate and the relevant aspects of solar panels, but also the regulations for facade claddings. Furthermore, research has been done into comparable systems for mounting High Pressure Laminate and solar panels. The program of requirements has been formulated based on the result of the literature research. First, the systems from the literature research were evaluated against the program of requirements. However, none of the systems met all the requirements. Additions were made to the program of requirements and these were used as a guideline for the development of the new system. In the second phase, the concept for the facade system has been developed. The design problems of the facade system are subdivided into different aspects. For each aspect different designs were made that were tested against the different criteria of the program of requirements. For each aspect, a design got the highest score and combined the designs with the highest score form the concept proposal. In the third phase of the research, prototypes were made for each aspect of the concept development.These prototypes were made with a 3D printer. This allowed the prototypes to be analysed in terms of their functionality. Because this method was very accessible, there was the possibility to make many prototypes. Next, a material analysis was made to determine the most suitable materials for the facade system. The material PLA, used to develop the prototypes, did not meet all the durability properties. In the material analysis, only materials that satisfied the durability properties were analysed.The mechanical characteristics of these materials were then compared with those of PLA, and the materials with approximately the same characteristics as PLA were selected to be used in the facade system. After that, the prototypes were structurally tested. This was done by means of a Finite Element Analysis. The first analysis was with the final prototype from the chapter 'prototyping'. Next, several iterations were made until the design met all the requirements. The last iteration was used to do a practical test. This practical test gave a good insight into the actual structural strength of the design. With the information from the practical test, the design was adjusted again and analysed by means of a Finite Element Analysis. After all parts met the functional and structural requirements, they were combined into the final design of the High Pressure Laminate Building-Integrated PhotoVoltaics facade system. The system is functioning, the tolerances have been taken into account and there are technical drawings of all components of the high pressure laminate building integrated photovoltaics facade system.